JP2005065087A - Stereoscopic display method and stereoscopic display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a highly realistic stereoscopic display method using a plurality of flat displays.
SOLUTION: First and second display devices are arranged on the front surface of an observer so that a light beam emitted from a first pixel 21 of the second display device is the first display device. A light ray incident on the left eye of the observer via one pixel 11 and emitted from the first pixel 21 of the second display device passes through the second pixel 12 of the first display device. The pixel 11 and the pixel 12 of the first display device and the pixel 21 of the second display device are arranged so as to enter the right eye of the observer, and the normality of the pixel 11 and the pixel 12 of the first display device is arranged. Let the normalized display brightness be r, and the normalized display brightness of the pixel 21 of the second display device be (1-r).
[Selection] Figure 1-1

Description

  The present invention relates to a stereoscopic display method and a stereoscopic display device, and more particularly, to a stereoscopic display method and a stereoscopic display device with high presence.

As a conventional stereoscopic display device, a parallax stereogram (1903, proposed by FE. Ive, USA) has been proposed for a long time (see Non-Patent Document 1 below).
Further, as a new stereoscopic display method, a DFD (Depth Fused 3D) method capable of expressing a continuous depth only by changing the luminance ratio between the front and rear two surfaces has been proposed (see Non-Patent Documents 2 and 3 below).

As prior art documents related to the invention of the present application, there are the following.
Supervised by Takehiro Izumi, edited by NHK Science and Technology Research Laboratories, “Basics of 3D Video”, Ohm, p. 145. Hideaki Takada, Shiro Suyama, Sakuichi Otsuka, Jinjo Kamihira, Shigenobu Sakai, “3D display without new glasses”, 3D Image Conference 2000 Proceedings, 4-5, pp.99-l02 (2000). Shiro Suyama, Hideaki Takada, “Developing 3D displays based on new phenomena”, NTT Technical Journal, 2002.8, Vol.14 No.8, pp.74-77).

The “Parallax Stereogram” described in Non-Patent Document 1 described above has a configuration in which two display devices are stacked with a certain gap, and one of them displays left and right parallax images. The display device is configured to display a simple slit for separating the left and right parallax images.
For this reason, the spatial resolution of the image to be displayed is half that of ordinary two-dimensional display, and there is a problem that it is difficult to express with high definition.
In the “DFD (Depth Fused 3D) type” stereoscopic display device described in Non-Patent Document 2 or Non-Patent Document 3, the problem of definition such as parallax stereogram is solved, but the display of the display object is performed. The range is basically a depth expression method that is displayed between two displays. Expressions that protrude to the front of the display that constitutes the display device or expressions that are retracted to the rear of the display are partly special. (E.g., if the display brightness of the front display is brighter than the ambient brightness and the display brightness of the rear display is darker than the ambient brightness, the display object appears to pop out from the display). There was a problem.

Further, the stereoscopic display devices described in Non-Patent Documents 1 to 3 have a configuration in which two display devices are stacked with a certain gap therebetween, so that the device itself becomes thick, and in particular, downsizing and thinning are required. There was a problem that it was difficult to apply to mobile devices.
The present invention has been made to solve the above-described problems of the prior art, and an object of the present invention is to provide a stereoscopic display method and a stereoscopic display device with a high sense of presence using a plurality of flat displays. is there.
The above and other objects and novel features of the present invention will become apparent from the description of this specification and the accompanying drawings.

Of the inventions disclosed in this application, the outline of typical ones will be briefly described as follows.
In order to solve the above-described problem, in the present invention, the first and second display devices are placed on the front surface of the observer so as to be emitted from the first pixel 21 of the second display device. A light ray enters the viewer's left eye via the first pixel 11 of the first display device, and a light ray emitted from the first pixel 21 of the second display device is emitted from the first display device. The pixels 11 and 12 of the first display device and the pixel 21 of the second display device are arranged so as to be incident on the right eye of the observer via the second pixel 12, and the first display The normalized display luminance of the pixel 11 and the pixel 12 of the device is r, and the normalized display luminance of the pixel 21 of the second display device is (1-r).
Thereby, in this invention, it becomes possible to represent a display object in the position which protruded ahead of the display apparatus with respect to the observer.

In the present invention, the first and second display devices are placed on the front surface of the observer so that the light emitted from the first pixels 21 of the second display device is the first display. A light ray incident on the left eye of the observer via the first pixel 11 of the device and emitted from the second pixel 22 of the second display device passes through the first pixel 11 of the first display device. The pixel 11 of the first display device, the pixel 21 and the pixel 22 of the second display device are arranged so as to be incident on the right eye of the observer via, and the normality of the pixel 11 of the first display device is arranged. The normalized display brightness is (1-r), and the normalized display brightness of the pixels 21 and 22 of the second display device is r.
Thereby, in this invention, it becomes possible to represent a display object in the position retracted | squeezed back rather than the 2nd display apparatus with respect to the observer.

In the present invention, the first display device and the second display device are arranged on the front surface of the observer so that the light emitted from the first pixel 21 of the second display device is the first display device. The light beam that has entered the left eye of the observer via the second pixel 12 and emitted from the second pixel 22 of the second display device passes through the first pixel 11 of the first display device. Then, the pixel 11 and the pixel 12 of the first display device and the pixel 21 and the pixel 22 of the second display device are arranged so as to enter the right eye of the observer, and the pixel 11 of the first display device. The normalized display luminance of the pixel 12 is r, and the normalized display luminance of the pixel 21 and the pixel 22 of the second display device is (1-r).
Accordingly, in the present invention, a three-dimensional object is expressed with respect to the observer at a position between the front surface and the second display device, in front of the first display device, or behind the second display device. It becomes possible to do.

Further, in the present invention, in order to reduce the size and thickness of the stereoscopic display device, a reflector is disposed at a position between the first display device and the second display device, and reflection of the display pixels on the rear surface is performed. The image is displayed on the back surface of the first display device, and the second display device is eliminated.
With such a configuration, the thickness of the display device can be reduced by half compared to the conventional case.

The effects obtained by the representative ones of the inventions disclosed in the present application will be briefly described as follows.
(1) According to the present invention, the range of expression as a stereoscopic display device can be expanded, and display with a higher presence can be achieved.
(2) According to the present invention, the thickness of the stereoscopic display device can be halved compared to the conventional one.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
Note that components having the same function are denoted by the same reference symbols throughout the drawings for describing the embodiment, and the repetitive description thereof will be omitted.
[Example 1]
FIG. 1-1 is a diagram illustrating a configuration of a stereoscopic display device according to Embodiment 1 of the present invention.
In this embodiment, a transparent display device is formed by stacking two transparent self-luminous display devices. As the transparent self-luminous display device, a display device in which display elements are integrated on a transparent substrate such as an EL display device (for example, a glass substrate) is used.
In this embodiment, an image of normalized display luminance (hereinafter simply referred to as display luminance) r is displayed on the pixel 1-1 and the pixel 1-2 of the first display device 1, and the second display device 2 An image having a display luminance (1-r) is displayed on the pixel 2-1. In FIG. 1-1, the luminance of pixels other than the pixel (1-1, 1-2, 2-1) is 0.
In addition, the front pixel 1-1 and the pixel 2-1 are arranged so that the light beam emitted from the pixel 2-1 enters the right eye via the pixel 1-1, and is similarly emitted from the pixel 2-1. The previous pixel 1-2 and the pixel 2-1 are arranged so that the emitted light enters the left eye via the pixel 1-2.

With this configuration, as shown in FIG. 1-1, for example, an image with light intensity 1 and an image with light intensity r are formed on the retinal image of the right eye, and the retinal image of the left eye. In this case, an image having a light intensity of 1 and an image having a light intensity r are formed.
In such a case, a human is observed as if there is an object having a luminance r at the stereoscopic display position 10 (corresponding to a position protruding forward from the display device 1), and the stereoscopic display position 20 has a luminance of 1. Observed as if there was an object.
By changing the value of the brightness parameter r, the brightness of the object displayed at the stereoscopic display position 10 can be changed.
As shown in FIG. 1-2, when the distance between the surfaces of the display device 1 and the display device 2 is d, the viewing distance is 1, and the distance between the right eye and the left eye is D, the stereoscopic display position 10 from the display device 1 is high. The length z can be expressed as a value determined by the viewing distance l and the surface distance d as shown in the following equation (1).
[Equation 1]
z = d / (1 + 2d / l) (1)
At that time, the interval x between the pixel 1-1 and the pixel 1-2 displayed on the display device 1 is expressed by the following equation (2).
[Equation 2]
x / 2 = D / 2 × {d / (d + 1)} (2)

By arranging the pixels (1-1, 1-2, 2-1) at the positions determined by the equations (1) and (2) and displaying the image with the luminance ratio described in FIG. 1-1, A display protruding from the screen at the stereoscopic display position 10 can be realized.
FIG. 1C is a diagram for explaining the operation when the viewing angle is rotated by θ (radian) in the present embodiment. When the rotation amount of the viewing angle is small (θ to 0), the position shift amount of the pixel (1-1, 1-2) can be approximated by d · θ.
In FIG. 1-3, when the pixel position is compared between the case where the viewing angle is not rotated and the case where the viewing angle is rotated by θ (radian), each pixel (1-1, 1-2) is referred to in the drawing. The case where it is parallel-shifted upward is illustrated.
By displaying pixels of luminance r simultaneously on each of the pixels 1-1 and 1-2 when the viewing angle is rotated and the pixels 1-1 and 1-2 when the viewing angle is not rotated, stereoscopic display is performed. The viewing angle that can be observed can be enlarged.
In the present embodiment, even when the parameter r is set to 0 or 1, and only one display surface is provided, stereoscopic viewing can be performed as in the present invention. However, in the present invention, the parameter r is set to an appropriate value in the range of 0 <r <1 and the display surface is set to two surfaces, thereby making it easier for the observer than in the case of only one display surface. Therefore, it is possible to obtain an excellent effect that stereoscopic viewing can be performed (a stereoscopic effect can be easily obtained).

[Example 2]
FIG. 2-1 is a configuration diagram of a stereoscopic display device that is Embodiment 2 of the present invention.
Also in this embodiment, two transparent self-luminous display devices are stacked to form a stereoscopic display device. As the transparent self-luminous display device, a display device in which display elements are integrated on a transparent substrate such as an EL display device (for example, a glass substrate) is used.
In this embodiment, an image having a display luminance (1-r) is displayed on the pixel 1-1 of the first display device 1, and displayed on the pixel 2-1 and the pixel 2-2 of the second display device 2. An image with luminance r is displayed. In FIG. 2A, the brightness of pixels other than the pixels (1-1, 2-1, 2-2) is 0.
In addition, the pixel 1-1 and the pixel 2-1 are arranged so that the light beam emitted from the pixel 2-1 enters the left eye via the pixel 1-1, and is similarly emitted from the pixel 2-2. The pixel 1-1 and the pixel 2-2 are arranged so that the received light enters the right eye via the pixel 1-1.
With such a configuration, as shown in FIG. 2A, for example, an image with light intensity 1 and an image with light intensity r are formed on the retinal image of the right eye, and the retinal image of the left eye. In this case, an image having a light intensity of 1 and an image having a light intensity r are formed.
In such a case, a human being observes as if there is an object with luminance 1 at the stereoscopic display position 10, and the luminance r is at the stereoscopic display position 20 (corresponding to a retracted position behind the display device 2). Observed as if there was an object.
By changing the value of the luminance parameter r, the luminance of the object displayed at the stereoscopic display position 20 can be changed and displayed.

As shown in FIG. 2B, when the surface distance between the display device 1 and the display device 2 is d, the viewing distance is 1, and the distance between the right eye and the left eye is D, the depth from the display device 2 at the stereoscopic display position 10 is shown. z ′ can be expressed as a value determined by the viewing distance l and the surface interval d as shown in equation (3).
[Equation 3]
z ′ = d × (1 + d / l) / (1−d / l) (3)
In addition, the distance x between the pixel 2-1 and the pixel 2-2 displayed on the display device 2 at that time can be expressed by the following equation (4).
[Equation 4]
x / 2 = (D / 2) × (d / l) (4)
By displaying the pixels (2-1, 2-2, 1-1) at the positions determined by the equations (3) and (4), and displaying the image with the luminance ratio described in FIG. 2-1, Display retracted from the screen at the stereoscopic display position 20 can be realized.

[Example 3]
FIG. 3A is a configuration diagram of a stereoscopic display device that is Embodiment 3 of the present invention.
Also in this embodiment, two transparent self-luminous display devices are stacked to form a stereoscopic display device. As the transparent self-luminous display device, a display device in which display elements are integrated on a transparent substrate such as an EL display device (for example, a glass substrate) is used.
In this embodiment, an image having a display luminance r is displayed on the pixels 1-1 and 1-2 of the first display device 1, and the pixels 2-1 and 2-2 of the second display device 2 are displayed. Then, an image of display luminance (1-r) is displayed. In FIG. 3A, the luminance of pixels other than the pixel (1-1, 1-2, 2-1, 2-2) is 0.
Further, although the pixel 1-1 and the pixel 2-1 are spaced apart from each other by the distance d, the display positions are the same. Similarly, the display positions of the pixels 1-2 and 2-2 are also the same.
Further, the pixel 1-2 and the pixel 2-1 are arranged so that the light beam emitted from the pixel 2-1 enters the left eye via the pixel 1-2, and is similarly emitted from the pixel 2-2. The pixel 1-1 and the pixel 2-2 are arranged so that the received light enters the right eye via the pixel 1-1.
With this configuration, as shown in FIG. 3A, for example, the right eye retinal image includes an image of light intensity r, an image of light intensity 1, and an image of light intensity (1-r). In addition, an image of light intensity (1-r), an image of light intensity 1, and an image of light intensity r are formed on the retinal image of the left eye.
In such a case, a human is observed as if there is an object with luminance r at the stereoscopic display position 10, and is observed as if there is an object with luminance 1 at the stereoscopic display position 20. It is observed as if there is an object with luminance (1-r) at the display position 30.
By changing the value of the luminance parameter r, the luminance of the object displayed at the stereoscopic display positions 10, 20, and 30 can be changed.
However, in this embodiment, the display object at the stereoscopic display position 20 has the display luminance 1 even if the parameter r is changed.

As shown in FIG. 3-2, when the surface distance between the display device 1 and the display device 2 is d, the viewing distance is 1, and the distance between the right eye and the left eye is D, the stereoscopic display position 10 from the display device 1 is high. The length z ₁ can be expressed as a value determined by the viewing distance l and the surface interval d as shown in equation (5).
The height z ₂ from the display device 2 of three-dimensional display position 20 is expressed as equation (6). Furthermore, the depth z ₃ from the display device 2 at the stereoscopic display position 30 can be expressed as in equation (7).
[Equation 5]
z ₁ = d / 2 × (1 + d / l) (5)
z ₂ = d / 2 (6)
z ₃ = d × (1 + d / l) / 2 (7)
Further, the interval between the pixel 1-1 and the pixel 1-2 of the display device 1 and the interval x between the pixel 2-1 and the pixel 2-2 of the display device 2 at that time can be expressed by the following equation (8).
[Equation 6]
x / 2 = (D / 2) × d / (2l + d) (8)
Luminances illustrating the pixels (1-1, 1-2, 2-1, 2-2) at the positions determined by the equation (8) (the pixels on the display device 1 are displayed with the luminance r). The pixel is displayed at a luminance (1-r)), whereby a stereoscopic object with luminance r is displayed at the stereoscopic display position 10, a stereoscopic object with luminance 1 at the stereoscopic display position 20, and luminance (1) at the stereoscopic display position 30. -R) can be displayed.

[Example 4]
FIG. 4A is a configuration diagram of a stereoscopic display device that is Embodiment 4 of the present invention.
Also in this embodiment, two transparent self-luminous display devices are stacked to form a stereoscopic display device. As the transparent self-luminous display device, a display device in which display elements are integrated on a transparent substrate such as an EL display device (for example, a glass substrate) is used.
In this embodiment, an image having a display luminance r is displayed on the pixels 1-1 and 1-2 of the first display device 1, and the pixels 2-1 and 2-2 of the second display device 2 are displayed. An image having a display luminance (1-r) is displayed. In FIG. 4A, the brightness of pixels other than the pixels (1-1, 1-2, 2-1, 2-2) is 0.
In the third embodiment, the display positions of the pixels 1-1 and 2-1 are the same, and the display positions of the pixels 1-2 and 2-2 are the same. This is an example of removing the condition.
In this embodiment, the pixel 1-1 and the pixel 2-1 are arranged so that the light beam emitted from the pixel 2-1 enters the right eye via the pixel 1-1. Similarly, the pixel 2-2 The pixel 1-2 and the pixel 2-2 are arranged so that the light emitted from the light enters the left eye via the pixel 1-2.
With such a configuration, as shown in FIG. 4A, for example, the retinal image of the right eye includes an image of light intensity r, an image of light intensity (1-r), and an image of light intensity 1. In addition, an image with a light intensity of 1, an image with a light intensity (1-r), and an image with a light intensity r are formed on the retinal image of the left eye.
In such a case, a human is observed as if there is an object with luminance r at the stereoscopic display position 10, and as if there is an object with luminance (1-r) at the stereoscopic display position 20. Further, it is observed as if there is an object with luminance 1 at the stereoscopic display position 30.
By changing the value of the luminance parameter r, the luminance of the object displayed at the stereoscopic display positions 10, 20, and 30 can be changed.

As shown in FIG. 4B, when the surface distance between the display device 1 and the display device 2 is d, the viewing distance is l, and the distance between the right eye and the left eye is D, the stereoscopic display position 10 from the display device 1 is high. The length z ₁ can be expressed as a value determined by the viewing distance l, the surface interval d, and the position z ₃ (medium parameter) of the _three- dimensional display position 30 as in the equation (11). The height _{z 2} from the display device 2 of three-dimensional display position 20 is expressed as equation (12). Here, it is borne parameters depth z ₃ from the display device 2 of three-dimensional display position 30.
[Equation 7]
z ₁ = (z ₃ + d) / {2 × (z ₃ + d) + l)} (9)
z ₂ = z ₃ × (d + 1) / (2z ₃ + d + 1) (10)
The distance _{X 1} of pixel 11 and pixel 1-2 to be displayed on the display device 1 at that time can be expressed by using the equation (11). Further, the interval _{x 2} pixels 2-1 and pixels 2-2 to be displayed on the display device 2 can be expressed using the expression (12).
[Equation 8]
_{x 1/2 = (D /} 2) × (z 3 + d) / (z 3 + d + l) ······ (11)
_{x 2/2 = z 3 ×} (d + l) / (2z 3 + d + l) ········· (12)
Luminances illustrating the pixels (1-1, 1-2, 2-1, 2-2) at the positions determined by the equations (11) and (12) (pixels on the display device 1 are displayed with luminance r). The pixels of the display device 2 are displayed at a luminance (1-r)), whereby a three-dimensional object having luminance r at the three-dimensional display position 10 and a three-dimensional object having luminance (1-r) at the three-dimensional display position 20 are displayed. Can be displayed at the stereoscopic display position 30.

[Example 5]
FIG. 5 is a configuration diagram of a stereoscopic display device that is Embodiment 5 of the present invention.
Also in this embodiment, two transparent self-luminous display devices are stacked to form a stereoscopic display device. As the transparent self-luminous display device, a display device in which display elements are integrated on a transparent substrate such as an EL display device (for example, a glass substrate) is used.
In this embodiment, an image having a display luminance r is displayed on the pixels 1-1 and 1-2 of the first display device 1, and the pixels 2-1 and 2-2 of the second display device 2 are displayed. An image having a display luminance (1-r) is displayed. In FIG. 5A, the brightness of pixels other than the pixels (1-1, 1-2, 2-1, 2-2) is 0.
The above-described fourth embodiment is a case where x ₁ > x ₂ , but this embodiment corresponds to a case where x ₁ <x ₂ .
In this embodiment, the pixel 1-1 and the pixel 2-1 are arranged so that the light beam emitted from the pixel 2-1 enters the left eye via the pixel 1-1. The pixel 1-2 and the pixel 2-2 are arranged so that the light beam emitted from the light enters the right eye via the pixel 1-2.
With this configuration, as shown in FIG. 5A, for example, the retinal image of the right eye has an image of light intensity 1, an image of light intensity r, and an intensity of light intensity (1-r). An image is formed, and a light intensity (1-r) image, an image with light intensity r, and an image with light intensity 1 are formed on the retina image of the left eye.
In such a case, a human being is observed as if there is an object with luminance 1 at the stereoscopic display position 10, and as if there is an object with luminance r at the stereoscopic display position 20.
By changing the value of the luminance parameter r, the luminance of the object displayed at the stereoscopic display positions 10 and 20 can be changed.

[Modifications of Examples 1 to 5]
FIG. 6 is a diagram illustrating a modification of the stereoscopic display device according to the first to fifth embodiments of the present invention.
The stereoscopic display device shown in FIG. 6 includes a first transparent self-luminous display device 201 and a second transparent self-luminous display device disposed behind the first transparent self-luminous display device 201 as viewed from the observer. Device 202, reflector 3 disposed behind second transparent self-luminous display device 202 as viewed from the observer, first transparent self-luminous display device 201, and second transparent self-luminous display device And a filter film 203 disposed between the second transparent self-luminous display device 202 and the reflection plate 3.
The video signal supplied to the first transparent self-luminous display device 201 and the second transparent self-luminous display device 202 may be a monochrome or color video signal. A case where a color video signal is supplied to the transparent self-luminous display device 201 and the second transparent self-luminous display device 202 will be described.
The transparent self-luminous display devices (201, 202) have, for example, a plurality of R (red), G (green), and B (blue) pixels arranged in a matrix.
Examples of such transparent self-luminous display devices (201, 202) include organic electroluminescence display devices and electroluminescence display devices such as inorganic electroluminescence display devices.

As shown in the schematic diagram of FIG. 7, the wavelength conversion film 205 includes a first portion 205a corresponding to an R (red) pixel in the transparent self-luminous display device (201, 202), and G (green). A second portion 205b corresponding to the pixel and a third portion 205c corresponding to the B (blue) pixel are included.
Here, when the wavelength of R (red) emitted from the transparent self-luminous display device (201, 202) is λRa, the wavelength of G (green) is λGa, and the wavelength of B (blue) is λBa. The first portion 205a of the wavelength conversion film 205 converts light having a wavelength of λRa into light having a wavelength of λRb with R (red) light of the same system.
Similarly, the second portion 205b of the wavelength conversion film 205 converts the light of the wavelength of λGa into the light of the same type of G (green) light, the light of the wavelength of λGb, and the third portion of the wavelength conversion film 205. The portion 205c converts light having a wavelength of λBa into light having a wavelength of λBb with B (blue) light of the same system.
The wavelength conversion film 205 functions as a transparent body for light having a wavelength of λRb, light having a wavelength of λGb, and light having a wavelength of λBb.
The filter film 203 has a function of blocking the passage of light having wavelengths of λRa, λGa, and λBa, but functions as a transparent body for light having a wavelength of λRb, light having a wavelength of λGb, and light having a wavelength of λBb. To do.

In the transparent self-luminous display devices (201, 202), the emitted light is irradiated in both directions on the observer side and the reflector side.
In the present embodiment, the light emitted from the first transparent self-luminous display device 201 and irradiated to the viewer side reaches the viewer as it is.
On the other hand, the light emitted from the first transparent self-luminous display device 201 and irradiated to the reflector side is blocked by the filter film 203 and reaches the second transparent self-luminous display device side. There is no.
The light emitted from the second transparent self-luminous display device 202 and applied to the observer side is blocked from passing by the filter film 203 and does not reach the observer side directly.
On the other hand, the light emitted from the second transparent self-luminous display device 202 and irradiated to the reflecting plate side is converted in wavelength when passing through the wavelength conversion film 205, reaches the reflecting plate 3, and reaches the reflecting plate 3. It is reflected by.
The light reflected by the reflector 3 (light whose wavelength has been converted) passes through the wavelength conversion film 205 again. However, the wavelength conversion film 205 and the filter film 203 are transparent to the light whose wavelength has been converted. Therefore, the light whose wavelength has been converted passes through the wavelength conversion film 205, the second transparent self-luminous display device 202, the filter film 203, and the first transparent self-luminous display device 201 for observation. Reach the person side.
Therefore, the stereoscopic display device shown in FIG. 6 is optically equivalent to the stereoscopic display devices shown in the first to fifth embodiments, and the depth can be shortened as compared with the stereoscopic display device shown in the aforementioned embodiments. Since it is possible, it becomes possible to constitute compactly.

In the stereoscopic display device shown in FIG. 6, the second transparent self-luminous display device 202 emits monochromatic light, and the first to third portions (205a, 205b, 205c) of the wavelength conversion film 205 are used. However, the monochromatic emission color may be converted into R (red), G (green), and B (blue) light.
For example, the second transparent self-luminous display device 202 emits blue emission light, and the first portion 205a of the wavelength conversion film 205 converts the blue light into R (red) light, and The second portion 205b of the wavelength conversion film 205 converts the blue light into G (green) light, and the third portion 205c of the wavelength conversion film 205 converts the blue light into a longer wavelength. The light is converted to B (blue) light.
The first transparent self-luminous display device 201 emits an R (red) color with a wavelength of λRa, a G (green) color with a wavelength of λGa, and a B (blue) color with a wavelength of λBa.
In this case, the first portion 205a of the wavelength conversion film 205 converts blue light into R (red) light of the same system to R (red) light having a wavelength of λRb, and wavelength conversion. The second portion 205b of the film 205 converts blue light into G (green) light of the same system to G (green) light having a wavelength of λGb, and the third portion 205 of the wavelength conversion film 205. The portion 205c converts blue light into B (blue) light of the same system and B (blue) light having a wavelength of λBb.

Further, the wavelength conversion film 205 functions as a transparent body for light having a wavelength of λRb, light having a wavelength of λGb, and light having a wavelength of λBb.
In addition, the filter film 203 has a function of blocking the passage of monochromatic emission light (for example, blue), light having a wavelength of λRa, λGa, and λBa, but light having a wavelength of λRb, light having a wavelength of λGb, and It functions as a transparent body for light having a wavelength of λBb.
Even in this case, the light emitted from the first transparent self-luminous display device 201 and irradiated to the reflector side is blocked by the filter film 203 and reaches the second transparent self-luminous display device side. There is nothing to do.
In addition, the light emitted from the second transparent self-luminous display device 202 and irradiated to the viewer side is blocked by the filter film 203 and does not reach the viewer side directly. The light emitted from the transparent self-luminous display device 202 irradiating the reflective plate side is converted in wavelength when passing through the wavelength conversion film 205, reaches the reflective plate 3, and is reflected by the reflective plate 3. Then, the light passes through the wavelength conversion film 205, the second transparent self-luminous display device 202, the filter film 203, and the first transparent self-luminous display device 201, and reaches the observer side.

FIG. 8 is a diagram illustrating a modification of the stereoscopic display device according to the first to fifth embodiments of the present invention.
The stereoscopic display device shown in FIG. 8 includes a first transparent self-luminous display device 211 and a second transparent self-luminous display device disposed behind the first transparent self-luminous display device 211 when viewed from the observer. Device 212, reflector 3 disposed behind second transparent self-luminous display device 212 as viewed from the viewer, first transparent self-luminous display device 211, and second transparent self-luminous display device 212, a linearly polarizing plate 213 disposed between the second transparent self-luminous display device 212 and the quarter-wave plate 215 disposed between the reflective plate 3.
Note that the video signals supplied to the first transparent self-luminous display device 211 and the second transparent self-luminous display device 212 may be monochrome or color video signals.
In the stereoscopic display device shown in FIG. 8, the transparent self-luminous display devices (211, 212) are transparent self-luminous display devices that emit light having a polarization direction in the first direction.
Examples of such transparent self-luminous display devices (211 and 212) include organic electroluminescence display devices, electroluminescence display devices such as inorganic electroluminescence display devices, and ultraviolet-excited fluorescence liquid crystal display devices. is there.
In addition, the polarization direction of the linearly polarizing plate 213 is a second direction orthogonal to the first direction described above.

In the transparent self-luminous display device (211, 212), the emitted light is emitted in both directions of the observer side and the reflector side, but the observer emits the emitted light from the first transparent self-luminous display device 211. The light irradiated to the side reaches the observer as it is.
On the other hand, the light emitted from the first transparent self-luminous display device 211 and irradiated to the reflecting plate side is the polarization direction of the linearly polarizing plate 213 and the polarization of the light emitted from the first transparent self-luminous display device 211. Since the directions are orthogonal to each other, the linear polarizing plate 213 prevents passage and does not reach the second transparent self-luminous display device side.
The light emitted from the second transparent self-luminous display device 212 and irradiated to the observer side includes the polarization direction of the linearly polarizing plate 213 and the polarization direction of the light emitted from the second transparent self-luminous display device 212. Are orthogonal to each other, the linear polarizing plate 213 prevents passage and does not reach the observer side directly.
On the other hand, the light emitted from the second transparent self-luminous display device 212 and irradiated to the reflecting plate side passes through the quarter-wave plate 215, reaches the reflecting plate 3, and is reflected by the reflecting plate 3. It passes through the quarter wave plate 215 again.

At this time, the light emitted from the second transparent self-luminous display device 212 and irradiated to the reflecting plate side is converted into left-handed (or right-handed) circularly polarized light by the quarter-wave plate 215. However, when it is reflected by the reflector 3, it is converted into right-handed (or left-handed) circularly polarized light.
This right-handed (or left-handed) circularly polarized light enters the quarter-wave plate 215 and is converted into linearly polarized light.
At this time, the polarization direction of the linearly polarized light converted by the quarter wavelength plate 215 is the same as the polarization direction of the linearly polarizing plate 213, so that the reflected light is reflected by the light emitted from the second transparent self-luminous display device 212. The light irradiated to the side passes through the second transparent self-luminous display device 212, the linearly polarizing plate 213, and the first transparent self-luminous display device 211, and reaches the observer side.
Therefore, the stereoscopic display device shown in FIG. 8 is also optically equivalent to the stereoscopic display devices shown in the first to fifth embodiments, and the depth can be shortened as compared with the stereoscopic display device shown in the aforementioned embodiments. Since it is possible, it becomes possible to constitute compactly.

FIG. 9 is a diagram illustrating a modification of the stereoscopic display device according to the first to fifth embodiments of the present invention.
The stereoscopic display device shown in FIG. 9 includes a first transparent display device 221, a second transparent display device 222 disposed behind the first transparent display device 221 as viewed from the observer, and an observer. The reflector 3 disposed behind the second transparent display device 222 and the quarter-wave plate 215 disposed between the first transparent display device 221 and the second transparent display device 222 are provided.
The transparent display device (221, 222) includes a waveguide 223 to which light from the light source 226 is irradiated and a polarized light irradiation means 225.
This polarized light irradiation means 225 has, for example, a plurality of cells arranged in a matrix, and can irradiate the light from the waveguide 223 to the outside or not to irradiate the outside for each cell. .
Therefore, by controlling each cell based on the supplied video signal, the polarized light irradiation means 225 can display a two-dimensional image. In this case, the brightness of the two-dimensional image displayed by the light irradiation means 225 can be changed according to the control state of each cell.
In addition, by arranging each light source of R (red), G (green), and B (blue), a two-dimensional image of a color image can also be displayed.

In the stereoscopic display device shown in FIG. 9, the light emitted from the polarized light irradiation means 225 is light having a polarization direction in the first direction, and light having a polarization direction that is orthogonal to the first direction. Passes through the polarized light irradiating means 225, but light whose polarization direction is the first direction cannot pass through the polarized light irradiating means 225.
In the transparent display devices (221, 222), the emitted light is irradiated in both directions of the observer side and the reflector side, but the light emitted to the observer side by the emitted light of the first transparent display device 221. Reaches the observer as it is.
On the other hand, since the light emitted from the first transparent display device 221 and irradiated to the reflector side is light having the polarization direction in the first direction, the polarization irradiation means 225 prevents the light from passing through the second transparent display device 221. It does not reach the transparent display device side.
Since the light emitted from the second transparent display device 222 and irradiated to the viewer side is light having the polarization direction in the first direction, the light is blocked by the polarized light irradiation means 225 and directly to the viewer side. Never reach.

On the other hand, the light emitted from the second transparent display device 222 and applied to the reflecting plate side passes through the quarter-wave plate 215, reaches the reflecting plate 3, is reflected by the reflecting plate 3, and is again 1 / 4 wave plate 215 passes.
At this time, the light emitted from the second transparent display device 222 and irradiated to the reflecting plate side is converted by the quarter wavelength plate 215 into left-handed (or right-handed) circularly polarized light. When reflected by the reflector 3, it is converted into right-handed (or left-handed) circularly polarized light.
This right-handed (or left-handed) circularly polarized light enters the quarter-wave plate 215 and is converted into linearly polarized light.
At this time, the polarization direction of the linearly polarized light converted by the ¼ wavelength plate 215 is orthogonal to the polarization direction of the light emitted from the polarized light irradiation means 225, and therefore reflected by the light emitted from the second transparent display device 222. The light irradiated on the plate side passes through the polarized light irradiation means 225 and the waveguide 223 constituting the second transparent display device 222 and the polarized light irradiation means 225 and the waveguide 223 constituting the first transparent display device 221. Then, it reaches the observer side.
Therefore, the stereoscopic display device shown in FIG. 9 is also optically equivalent to the stereoscopic display devices shown in the first to fifth embodiments, and the depth can be shortened as compared with the stereoscopic display device shown in the aforementioned embodiments. Since it is possible, it becomes possible to constitute compactly.

[Example 6]
FIG. 10 shows a configuration diagram of a stereoscopic display device according to a sixth embodiment of the present invention.
In this embodiment, the display device 1 and the reflection plate 3 constitute a stereoscopic display device.
The position of the reflecting plate 3 is arranged at a position intermediate between the display device 1 and the display device 2 shown in the first embodiment, and the mirror image of the display device 2 is displayed on the back surface of the display device 1 (the display image is displayed on the transmission type display). The image is displayed on the side that is displayed as an image viewed from the reverse side.
As in the first embodiment, the display device 1 displays an image of the display luminance r on the pixels 1-1 and 1-2 on the front surface side of the display device 1 and the pixel 2 on the back surface side of the display device 1. An image having a display luminance (1-r) (a mirror image of the image displayed on the pixel 2-1 of Example 1) is displayed on −1 ′.
By adopting such a configuration, the thickness of the stereoscopic display device can be reduced by half compared to the first embodiment.
10 can be similarly applied to the second to fifth embodiments of the present invention, and the thickness of the stereoscopic display device can be reduced to half.

FIG. 11 is a diagram showing an example of the display device 1 shown in FIG.
The display device shown in FIG. 11 includes a transparent self-luminous display device 200 and a reflector 3 disposed behind the transparent self-luminous display device 200.
The transparent self-luminous display device 200 includes, for example, a plurality of pixels arranged in a matrix, and the plurality of pixels include a front-side pixel 231 including pixels (1-1, 1-2), and a pixel. It is roughly divided into a rear surface pixel 232 including 2-1 ′.
Further, on the observer side of the transparent light-emitting display device 200, light shielding means 233 is formed on the rear pixel, and on the side opposite to the observer side of the transparent light-emitting display device 200, for the front side. A circularly polarizing plate 235 is provided on the pixels.
Here, the transparent self-luminous display device 200 includes an organic electroluminescence display device or an electroluminescence display device such as an inorganic electroluminescence display device.
The light shielding means 233 is composed of a light shielding layer (mask) or a mirror.
In the transparent self-luminous display device 200, the emitted light is applied to both the observer side and the reflector side.

In the stereoscopic display device shown in FIG. 11, the light emitted from the front pixel 231 and irradiated to the viewer side reaches the viewer as it is.
On the other hand, the light emitted from the front pixel 231 and irradiated to the reflecting plate side reaches the reflecting plate 3 via the circularly polarizing plate 235, is reflected by the reflecting plate 3, and reaches the circularly polarizing plate 235. To do.
At this time, the light emitted from the front pixel 231 and irradiated to the reflector side is converted into left-handed (or right-handed) circularly polarized light by the circularly polarizing plate 235. When reflected, the light is converted into right-handed (or left-handed) circularly polarized light. Therefore, the light emitted from the front-side pixel 231 irradiates the reflecting plate and is reflected by the reflecting plate 3. It cannot pass through the polarizing plate 235.
Therefore, the light emitted from the front pixel 231 and irradiated to the reflector side does not reach the observer.
Further, the light emitted from the pixel 232 for the rear surface and irradiated on the observer side is blocked from passing by the light shielding means (light shielding layer or mirror) 233, and therefore does not reach the observer directly. .
On the other hand, the light emitted from the pixel 232 for the rear surface and irradiated on the reflection plate side reaches the reflection plate 3, is reflected by the reflection plate 3, and passes through the circularly polarizing plate 235 for observation because it is almost non-polarized. Reach the person.

FIG. 12 is a diagram illustrating an example of the display device 1 illustrated in FIG.
The display device shown in FIG. 12 includes a transparent self-luminous display device 200, a reflective plate 3 disposed behind the transparent self-luminous display device 200, and the transparent self-luminous display device 200 and the reflective plate 3. And a quarter-wave plate 237 to be disposed.
The transparent self-luminous display device 200 includes, for example, a plurality of pixels arranged in a matrix, and the plurality of pixels are roughly classified into a front pixel 231 and a rear pixel 232.
Further, on the observer side of the transparent self-luminous display device 200, light shielding means 233 is formed on the rear pixel, and on the side opposite to the observer side of the transparent self-luminous display device 200, for the front surface. A linearly polarizing plate 236 is provided on the pixels.
Here, the transparent self-luminous display device 200 includes an organic electroluminescence display device or an electroluminescence display device such as an inorganic electroluminescence display device.
The light shielding means 233 is composed of a light shielding layer (mask) or a mirror.
The video signal supplied to the front pixel 231 and the rear pixel 232 may be a monochrome or color video signal.
In the transparent self-luminous display device 200, the emitted light is applied to both the observer side and the reflector side, but the light emitted from the front pixel 231 and applied to the reflector side is: The light passes through the linear polarizing plate 236 and the quarter wavelength plate 237, reaches the reflection plate 3, is reflected by the reflection plate 3, passes through the quarter wavelength plate 237, and reaches the linear polarization plate 236.

At this time, the light emitted from the front-side pixel 231 and radiated to the reflecting plate side is circularly polarized leftward (or clockwise) by the linearly polarizing plate 236 and the quarter-wave plate 237. Although it is converted, when it is reflected by the reflector 3, it is converted into right-handed (or left-handed) circularly polarized light.
The right-handed (or left-handed) circularly polarized light is incident on the quarter-wave plate 237 and converted into linearly polarized light.
At this time, the polarization direction of the linearly polarized light converted by the quarter wavelength plate 237 differs from the polarization direction of the linearly polarizing plate 236 by 90 °, so that the light emitted from the front pixel 231 was irradiated to the reflective plate side. Light cannot pass through the linear polarizer 236.
Therefore, the light emitted from the front pixel 231 and irradiated to the reflector side does not reach the observer.
Further, the light emitted from the pixel 232 for the rear surface and irradiated on the observer side is blocked from passing by the light shielding means (light shielding layer or mirror) 233, and therefore does not reach the observer directly. .
On the other hand, the light emitted from the pixel 232 for the rear surface and irradiated to the reflecting plate side reaches the reflecting plate 3, is reflected by the reflecting plate 3, and is almost non-polarized. It passes through the linear polarizing plate 236 and reaches the observer.
As described above, the linearly polarizing plate 236 and the quarter wavelength plate 237 have a function of converting the light emitted to the reflecting plate side with the light emitted from the front pixel 231 into circularly polarized light. Therefore, you may make it comprise the circularly-polarizing plate 235 of above-mentioned Embodiment 1 with a linearly-polarizing plate and a quarter wavelength plate.

According to the present embodiment, for example, a stereoscopic display object is provided not only between the display surfaces of the display device 1 and the display device 2 shown in FIG. 1-1 but also in front of the display device 1 or behind the display device 2. Can be displayed.
Thereby, the range of expression as a stereoscopic display device can be expanded, and display with higher presence can be realized.
Furthermore, unlike the conventional parallax barrier stereogram method, the configuration of the present invention can utilize the definition of the display device, which is a component of the stereoscopic display device, as it is, thereby realizing a display with high definition. Is possible.
In addition, if the configuration of the above-described embodiment 6 is used, the thickness of the stereoscopic display device can be halved compared to the conventional one, and the display device itself, which is a component thereof, can be made into one sheet. Therefore, there is a great advantage in reducing the size and thickness of the stereoscopic display device, and there is an advantage that the device configuration cost can be greatly reduced.
Although the invention made by the present inventor has been specifically described based on the above-described embodiment, the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the scope of the invention. Of course.

It is a figure which shows the structure of the three-dimensional display apparatus of Example 1 of this invention. It is a figure explaining the pixel display method of Example 1 of this invention. In Example 1 of this invention, it is operation | movement explanatory drawing when a viewing angle rotates (theta) (radian). It is a figure which shows the structure of the three-dimensional display apparatus of Example 2 of this invention. It is a figure explaining the pixel display method of Example 2 of this invention. It is a figure which shows the structure of the three-dimensional display apparatus of Example 3 of this invention. It is a figure explaining the pixel display method of Example 3 of this invention. It is a figure which shows the structure of the three-dimensional display apparatus of Example 4 of this invention. It is a figure explaining the pixel display method of Example 4 of this invention. It is a figure which shows the structure of the three-dimensional display apparatus of Example 5 of this invention. It is a figure which shows the modification of the three-dimensional display apparatus of Examples 1-5 of this invention. It is a schematic diagram for demonstrating the wavelength conversion film shown in FIG. It is a figure which shows the modification of the three-dimensional display apparatus of Examples 1-5 of this invention. It is a figure which shows the modification of the three-dimensional display apparatus of Examples 1-5 of this invention. It is a figure which shows the structure of the three-dimensional display apparatus of Example 6 of this invention. It is a figure which shows an example of the display apparatus shown in FIG. It is a figure which shows an example of the display apparatus shown in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1, 2 Display device 1-1, 1-2, 2-1, 2-1 ', 2-2, 231,232 Pixel 3 Reflector 10, 20, 30 Stereoscopic display position 200, 201, 202, 211, 212 Transparent self-luminous display device 203 Filter film 205 Wavelength conversion film 205a First portion 205b Second portion 205c Third portion 213, 236 Linearly polarizing plate 215, 237 1/4 wavelength plate 221, 222 Transparent display device 223 Waveguide 225 Polarized light irradiation means 226 Light source 233 Mask or mirror 235 Circularly polarizing plate

Claims (13)

As viewed from the observer, the first display device and the second display device are arranged in the order of the first display device and the second display device,
A light beam emitted from the first pixel 21 of the second display device enters the left eye of the observer via the first pixel 11 of the first display device, and the second display The pixels 11 of the first display device and the light rays emitted from the first pixel 21 of the device enter the right eye of the observer via the second pixel 12 of the first display device; A pixel 12 and a pixel 21 of the second display device are disposed;
The normalized display brightness of the pixels 11 and 12 of the first display device is r,
A stereoscopic display method, wherein the normalized display luminance of the pixel 21 of the second display device is set to (1-r). As viewed from the observer, the first display device and the second display device are arranged in the order of the first display device and the second display device,
A light beam emitted from the first pixel 21 of the second display device enters the left eye of the observer via the first pixel 11 of the first display device, and the second The pixel 11 of the first display device so that the light beam emitted from the second pixel 22 of the display device enters the right eye of the observer via the first pixel 11 of the first display device. And the pixel 21 and the pixel 22 of the second display device are arranged,
The normalized display luminance of the pixel 11 of the first display device is (1-r),
A stereoscopic display method, wherein the normalized display luminance of the pixel 21 and the pixel 22 of the second display device is r. As viewed from the observer, the first display device and the second display device are arranged in the order of the first display device and the second display device,
A light beam emitted from the first pixel 21 of the second display device enters the left eye of the observer via the second pixel 12 of the first display device, and the second display The pixels 11 of the first display device and the light rays emitted from the second pixel 22 of the device enter the right eye of the observer via the first pixel 11 of the first display device; A pixel 12, and a pixel 21 and a pixel 22 of the second display device,
The normalized display brightness of the pixels 11 and 12 of the first display device is r,
A stereoscopic display method, wherein normalized display luminance of the pixel 21 and the pixel 22 of the second display device is set to (1-r). A reflector is disposed behind the second display device as viewed from the observer,
A light beam emitted from a pixel of the second display device is reflected by the reflector, passes through the first display device, and is incident on the right eye and the left eye of the observer. The three-dimensional display method according to any one of claims 1 to 3. A reflector is disposed instead of the second display device,
The first display device includes a front pixel whose direction of irradiation light is on the viewer side,
A rear surface pixel constituting the pixel of the second display device in which the direction of the irradiation light is opposite to the observer;
The light beam emitted from the pixel for the rear surface is reflected by the reflecting plate, passes through the first display device, and is incident on the right eye and the left eye of the observer. The three-dimensional display method according to any one of claims 1 to 3. A first display device arranged in front of the observer;
A second display device disposed on the opposite side of the viewer from the first display device, the second display device being placed over the display device;
A light beam emitted from the first pixel 21 of the second display device enters the left eye of the observer via the first pixel 11 of the first display device, and the second display The pixels 11 of the first display device and the light rays emitted from the first pixel 21 of the device enter the right eye of the observer via the second pixel 12 of the first display device; A pixel 12 and a pixel 21 of the second display device are disposed;
The normalized display brightness of the pixels 11 and 12 of the first display device is r,
The stereoscopic display device, wherein the normalized display luminance of the pixel 21 of the second display device is (1-r). A first display device arranged in front of the observer;
A second display device disposed on the opposite side of the viewer from the first display device, the second display device being placed over the display device;
A light beam emitted from the first pixel 21 of the second display device enters the left eye of the observer via the first pixel 11 of the first display device, and the second The pixel 11 of the first display device so that the light beam emitted from the second pixel 22 of the display device enters the right eye of the observer via the first pixel 11 of the first display device. And the pixel 21 and the pixel 22 of the second display device are arranged,
The normalized display luminance of the pixel 11 of the first display device is (1-r),
3. A stereoscopic display device, wherein the normalized display brightness of the pixels 21 and 22 of the second display device is r. A first display device arranged in front of the observer;
A second display device disposed on the opposite side of the viewer from the first display device, the second display device being placed over the display device;
A light beam emitted from the first pixel 21 of the second display device enters the left eye of the observer via the second pixel 12 of the first display device, and the second display The pixels 11 of the first display device and the light rays emitted from the second pixel 22 of the device enter the right eye of the observer via the first pixel 11 of the first display device; A pixel 12, and a pixel 21 and a pixel 22 of the second display device,
The normalized display brightness of the pixels 11 and 12 of the first display device is r,
A stereoscopic display device, wherein the normalized display luminance of the pixel 21 and the pixel 22 of the second display device is (1-r). A reflector disposed behind the second display device as seen from the observer;
A wavelength conversion unit that is disposed between the second display device and the reflector and converts the light emitted from the second display device into light having a predetermined wavelength;
The first display device and the second display device are disposed between the first display device and the second display device to prevent light emitted from passing through the first display device and the second display device, and converted by the wavelength conversion unit. A filter film that transmits light of the predetermined wavelength;
A light beam emitted from a pixel of the second display device is reflected by the reflector, passes through the first display device, and is incident on the right eye and the left eye of the observer. The stereoscopic display device according to any one of claims 6 to 8. A reflection mirror disposed behind the second display device as seen from the observer;
A quarter-wave plate disposed between the second display device and the reflection mirror;
A linearly polarizing plate disposed between the first display device and the second display device, the polarization direction of which is the first direction;
A light beam emitted from a pixel of the second display device is reflected by the reflector, passes through the first display device, and is incident on the right eye and the left eye of the observer. The stereoscopic display device according to any one of claims 6 to 8. A reflection mirror disposed behind the second transparent display device as viewed from the observer;
A quarter-wave plate disposed between the second transparent display device and the reflection mirror;
The first transparent display device includes a waveguide,
A light source for irradiating the waveguide with irradiation light;
It is arranged on the viewer side of the waveguide, and the irradiation light in the waveguide irradiates the light whose polarization direction is the first direction to the outside, and the polarization direction is the light of the first direction. Polarization irradiating means for preventing light from passing and allowing light in a second direction whose polarization direction is orthogonal to the first direction to pass through,
The second transparent display device includes a waveguide,
A light source for irradiating the waveguide with irradiation light;
It is disposed on the reflection mirror side of the waveguide, irradiates light having a polarization direction of the first direction with irradiation light in the waveguide, and the polarization direction of the light of the first direction. Polarization irradiating means for preventing light from passing and allowing light in a second direction whose polarization direction is orthogonal to the first direction to pass through,
A light beam emitted from a pixel of the second display device is reflected by the reflector, passes through the first display device, and is incident on the right eye and the left eye of the observer. The stereoscopic display device according to any one of claims 6 to 8. A reflector is disposed instead of the second display device,
The first display device includes a front pixel whose direction of irradiation light is on the viewer side,
A rear surface pixel constituting a pixel of the second display device, the direction of the irradiation light being opposite to the observer;
Light blocking means provided on the rear surface pixels on the viewer side of the first display device;
A circularly polarizing plate provided on the front pixel on the side opposite to the viewer side of the first display device;
The light beam emitted from the pixel for the rear surface is reflected by the reflecting plate, passes through the first display device, and is incident on the right eye and the left eye of the observer. The stereoscopic display device according to any one of claims 6 to 8. A reflector is disposed instead of the second display device,
A quarter-wave plate disposed between the first display device and the reflection mirror;
The first display device includes a front pixel whose direction of irradiation light is on the viewer side,
A rear surface pixel constituting a pixel of the second display device, the direction of the irradiation light being opposite to the observer;
Light blocking means provided on the rear surface pixels on the viewer side of the first display device;
A linearly polarizing plate provided on the front pixel on the side opposite to the viewer side of the first display device;
The light beam emitted from the pixel for the rear surface is reflected by the reflecting plate, passes through the first display device, and is incident on the right eye and the left eye of the observer. The stereoscopic display device according to any one of claims 6 to 8.

Images