JPH04159529A - Three-dimensional image display device - Google Patents

Abstract

PURPOSE:To make the device light in weight and to improve the visibility of a light beam by determining the position and the dimensions so that a lenticular plate and an image formation screen plate are opposed through a spacer in the peripheral part, and opposed through an air layer in other part than the peripheral part, and a focal plane of the lenticular plate exists on the screen plate. CONSTITUTION:The device is constituted so that a lenticular plate 12 and an image formation screen plate 14 are opposed through a spacer 16 having prescribed width and thickness in the peripheral part, and opposed through an air layer 17 in other part than the peripheral part, and the position and the dimensions are determined so that a focal plane of the lenticular plate 12 exists on the surface 15 to which a diffusion processing is performed of the screen plate 14. In such a way, weight of the whole display device can be lightened and its thickness can be thinned. Also, a transmission factor of a light beam can be enhanced, and a distinct image can be obtained.

Description

[Detailed Description of the Invention] <Industrial Application Field> The present invention relates to a display device that obtains a three-dimensional effect through a lenticular plate, and in particular, from an image display device such as a television,
The present invention relates to a three-dimensional image display device used for observing three-dimensional images having horizontal parallax.

<Prior art> A lenticular plate used for stereoscopic vision etc. is shown in Fig. 3 (a).
), the lens plate 30 has a periodic curvature in the horizontal direction and has a configuration in which many cylindrical lenses are arranged,
Usually, as shown in the cross-sectional explanatory view of one cylindrical lens shown in FIG. 3(b), the focus is focused on the smooth back surface 35.

In the case of observing three-dimensional printed matter, on the back of the lenticular plate, multiple images (two or more) with parallax are divided into linear shapes according to the characteristics of the lens, and then compressed and reconstructed. Two images 38 are formed.

During observation, the left and right human eyes see images at different positions on the back side of the lenticular plate (that is, images with parallax), giving a three-dimensional effect.

<Problem to be solved by the invention> However, with the above-mentioned conventional lenticular plate,
Due to the required optical properties, the focus should not be on the smooth surface of the back surface, so the thickness of the lenticular plate should be
It depends on the pitch and radius of curvature of the cylindrical lens.

In order to reduce the thickness of the lenticular plate, it is possible to reduce the pitch and radius of curvature of the cylindrical lens.

However, depending on the size and configuration of the three-dimensional image to be displayed, it may not be possible to form a lenticular plate with a small pinch or radius of curvature.

Further, acrylic resin is mainly used as a material for the lenticular plate, but even though the resin is colorless and transparent, light rays passing through it become unclear due to scattering and the like.

The present invention aims to improve the lenticular plate, which is required to have a large screen, from the viewpoints of (1) weight reduction and (2) improvement in the clarity of light rays.

<Means for Solving the Problems> In other words, the present invention has a lenticular plate and an imaging screen plate facing each other with a spacer interposed in the periphery and an air layer in the area other than the periphery. 3. The focal plane is configured in such a manner that its position and dimensions are determined so that the focal plane lies substantially on the screen plate.
It is a dimensional image display device.

In some cases, the three-dimensional image display device may have a configuration that does not include an image forming screen plate.

Further, an image forming screen plate is located between two opposing lenticular plates, and is laminated together with a spacer in the peripheral part and an air layer in the other part, and the focal point of both the lenticular plates. Place the surface so that it is almost on the screen board! This is a three-dimensional image display device characterized by having a configuration in which the dimensions and dimensions are determined.

Three-dimensional image display devices using lenticular plates can be classified into (a) two-image type and (b) multi-image type based on the number of images with parallax.

The shape of the cylindrical lens must be changed between the two-image type and the multi-image type lenticular plate, and an example of this will be shown below for the four-image type.

(R: radius of curvature, P: pitch, L: thickness) If the product size is large, 2 m x 3 m, and the above lenticular plate is made of acrylic resin, its weight will be 360 kg in (a) and 360 kg in (b). ) is 104 kg,
It becomes very heavy and expensive.

As an imaging screen plate on which light rays are focused and an image is to be displayed, a diffusion sort (provisional) having the following configuration can be considered, for example.

■Sheet that diffuses light by incorporating an opacifying agent.

■Made by mixing a diffusing agent such as silica into transparent resin.

■One side of a transparent resin board is treated with a cape (the surface is shaped into an uneven shape).

■One side of a transparent resin board is painted or coated with a transparent paint containing a solid content of a diffusing agent such as silica.

Effect> In the three-dimensional image display device having the configuration of the present invention, the lens-like portion having light collecting property is a thin plate-like portion, and the subsequent straight traveling portion (optical path) of the light is an air layer, so that the entire display device is It has the advantage that it is very light in weight, and the image that is focused on the imaging screen, which is the focal plane, is clear and unaffected by scattering and the like.

<Example> A more detailed explanation will be given below with examples.

<Example-1> FIG. 1 is an explanatory diagram showing an example (two-image type) of a three-dimensional image display device 10 according to the present invention, and FIG. 1(a) is an overall perspective view, and FIG. (b) is a partial cross-sectional explanatory diagram of the A-A cross section,
FIG. 1(c) is an explanatory cross-sectional view showing one cylindrical lens.

A lenticular plate 12 and an image forming screen plate 14 are arranged to face each other with a spacer 16 having a predetermined width and thickness in the periphery interposed therebetween, and the focal plane of the lenticular plate 12 is approximately at the screen plate 14. It exists on 15 surfaces that have been subjected to the diffusion process.

The dimensions of the three-dimensional image display device of this example are shown in Table 1 below.

Here, each symbol represents the radius of curvature R, pitch p, and thickness of the lenticular plate.1 The thickness of the entire display device.

This refers to the thickness S of the imaging screen plate and the thickness d of the spacer.

As a comparative example, Table 1 shows the dimensions of a three-dimensional image display device made of a lenticular plate according to the prior art and having the configuration shown in FIG. 3(a).

In addition, the weight W of the display device and the light transmittance T (
If the light source light emitted from the projector is taken as 100,
A comparison of the percentage of light reaching the observer is also shown in the same table.

In addition, the area of the display device is 700 mm x 900 mm in both Example-1 and Comparative Example.

(Margins below) Table 1 In this example, the thickness D of the entire display device was reduced due to the difference in refractive index between the lens-shaped portion and the air layer inside. This is because the focal length of the lens has become shorter. (See Figure 1(c).

In the figure, the dotted line indicates the optical path of the light ray in the comparative example. Furthermore, a usage method in which the display device according to the present example is applied to a liquid crystal video projector is shown in FIG. 1(d).

On the screen surface 18 on which the image is displayed by the projector, an image with parallax is projected so that two images can be viewed stereoscopically, so that two images are displayed at l pitch corresponding to the pinch of the cylindrical lens. has been done.

At this time, if the screen surface 18 can function as the image forming screen plate 14 in this display device, the image forming screen plate 14 is not necessarily required.

The observer views the parallax images on the screen surface 18 with his left and right eyes through the display device from a predetermined distance, and can obtain a three-dimensional image.

In this embodiment, a two-image type display device has been described, but the same applies to a multi-image type display device in which the cylindrical lenses have different shapes.

Even in the case of a multi-image type, the observer can obtain a three-dimensional image, but the multi-image type has the advantage that the headrest that can be viewed stereoscopically is wider.

<Example-2> FIG. 2 is an explanatory diagram showing another example of the present invention.
FIG. 2(a) is an overall perspective view, FIG. 2(b) is a partial cross-sectional explanatory view taken along the line A-A, and FIG. 2(c) is a cross-sectional explanatory view showing a pair of cylindrical lenses.

Projection side lenticular plate 22 and imaging screen plate 2
4 is a spacer 26 having a predetermined width and thickness on the periphery.
A similar observation side lenticular Fi 23 is also arranged on the observation side, facing each other via a spacer 27, and the corner surfaces of both the lenticular plates are as follows.
It is arranged to exist approximately on the 25th surface of the screen plate 24 which has been subjected to the diffusion treatment.

Further, FIG. 2(d) shows how to use the display device according to this embodiment applied to a liquid crystal video projector.

A plurality of projectors are arranged at predetermined positions on the projection side and project parallax images toward the viewing side.

The projected image is condensed by the projection side lenticular plate 22 and formed on the image forming screen plate 24 so that a plurality of images are displayed at l pitch corresponding to the pinch of the cylindrical lens. .

The observer views the observation side lenticular plate 23 from a predetermined distance.
Through this, the parallax images on the screen plate 24 are viewed with the left and right eyes, respectively, and a three-dimensional image can be obtained.

<Example-3> FIG. 4 is an explanatory diagram showing another embodiment of the present invention.

For example, there is a structure in which an image is displayed using light passed from a light source through a liquid crystal display device.

On the display surface of the liquid crystal display device 40, a plurality of image parts 44 (portions where transparent electrodes face each other and become transparent or non-transparent by driving the liquid crystal) are arranged in a predetermined pinch. Operation (transparent/non-transparent)
An image pattern is constructed by (FIG. 4(a)) In such a display format, there is no need for an imaging screen surface (for example, subjected to a diffusion process) to form a display image.

On the display surface of the liquid crystal display device 40, there is a display screen 3 having a configuration in which the image forming screen plate 14 is not provided in FIG.
The dimensional image display device 10 is mounted as shown in FIG. 4(b).

The observer views the parallax images on the display surface with his left and right eyes through the display device from a predetermined distance, and can obtain a three-dimensional image.

Note that in this embodiment, the case of a liquid crystal display device has been described, but the present invention is not limited to this.
Other display devices that do not require an image forming screen include EL (electroluminescence) displays and plasma displays, and the present invention is also applicable to these.

<effect> The effects of the present invention can be enumerated as follows.

■By using a hollow structure, the weight of the entire display device can be reduced.

■The overall thickness of the display device can be reduced.

■It is possible to increase the transmittance of light rays and obtain clear images.

■The amount of transparent resin used for the lenticular plate can be reduced, and the cost of the display device can be reduced.

[Brief explanation of drawings]

FIG. 1, FIG. 2, and FIG. 4 are explanatory diagrams showing a three-dimensional image display device of the present invention and a display method using the device. FIG. 10.20.30...Three-dimensional image display device 1.2, 2
2.23...Lenticular plates 14, 24...
・Image forming screen plate 16.26.27...Spacer 15.25.35...Diffusion surface 17.28...Air layer 18...Screen surface 38...Parallax image 40...Liquid crystal Display device 44
...Image part Fig. 3(b) Fig. 4(a) O Fig. 4(b)

Claims (4)

[Claims] (1) A lens plate having a periodic curvature in the horizontal direction and an image forming screen plate are opposed to each other with a spacer interposed in the peripheral part and an air layer in the other part, and the focal point of the lens plate A three-dimensional image display device, characterized in that the position and dimensions of the surface are determined so that the surface substantially lies on the screen plate. (2) A plurality of right-eye images and left-eye images having parallax are formed on the imaging screen plate, each corresponding to the pitch of the lenses. 3D image display device. (3) The three-dimensional image display device according to claim (1), which does not include an imaging screen plate. (4) A lens plate having a periodic curvature in the horizontal direction and a similar lens plate on the back side face each other, and the image formation screen plate is located between the two lens plates in the peripheral area. The lens plates are laminated together via a spacer and an air layer in areas other than the periphery, and the positions and dimensions of the lens plates are determined so that the focal planes of both lens plates are approximately located on the screen plate. A three-dimensional image display device characterized by: