JP2001183587A - Stereoscopic image display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a stereoscopic image display device which eliminates the need for troublesome driving control and allows an image observer to recognize a stereoscopic image of good quality free of a flicker. SOLUTION: A reflecting and polarizing screen 10 is used which has a reflection axis and a transmission axis almost orthogonal to each other, reflects incident light of a polarized light component along the reflection axis, and transmits incident light of a polarized light component along the transmission axis, an ocular polarizing plate 20 for the left eye is arranged in front of the left eye of an observer 19 so that its transmission axis is almost in parallel to the reflection axis of the screen 10, and an ocular polarizing plate 21 for the right eye is arranged in front of the right eye so that its transmission axis is almost parallel to the transmission axis of the screen 10. Then one image light L for the left eye which is projected on the front of the screen 10 by a left-eye image projecting means 13 and reflected by the screen 10 is observed with the left eye of the observer 16 through the left-eye ocular polarizing plate 20 and the right-eye image light R which is projected on the back of the screen 10 by a right-eye image projecting means 16, transmitted through the screen 10, and projected on its front is observed with the right eye through the right-eye ocular polarizing plate 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.

[0002]

2. Description of the Related Art A three-dimensional image display apparatus converts an image for a left eye and an image for a right eye having a displacement corresponding to a difference in observation angle between a left eye and a right eye with an image observer's left and right eyes. , The image observer recognizes a stereoscopic image in which the image for the left eye and the image for the right eye are combined.

FIG. 3 is a plan view showing a conventional three-dimensional image display device. The three-dimensional image display device includes a screen 1 on which image light is projected and an image light for the left eye.
-Eye image projector 2 for projecting light toward the screen, and right-eye image projector 3 for projecting image light for the right eye toward the screen 1
And optical shutter elements 5 and 6 for the left and right eyes arranged in front of the left and right eyes of the image observer 4, respectively.

In this stereoscopic image display apparatus, a reflection type screen is used as the screen 1, and the left-eye image projector 2 and the right-eye image projector 3 are arranged in front of the screen 1, that is, in the projection mode. They are arranged side by side on the viewing side of the image.

The left-eye image projector 2 and the right-eye image projector 3
Is a projector, for example. The left-eye image projector 2 projects image light for the left eye onto the screen 1 as shown by a solid line in the figure, and the right-eye image projector 3 projects image light for the right eye. The image is projected on the screen 1 as shown by a broken line in the figure.

The optical shutter elements 5 and 6 for the left eye and the right eye are formed, for example, as a single film on the inner surfaces of a pair of transparent substrates opposed to each other with a liquid crystal layer in which liquid crystal molecules are twist-oriented. And a TN (twisted nematic) liquid crystal element in which polarizing plates are arranged on the outer surfaces of the pair of transparent substrates, respectively. The optical shutter elements 5 and 6 for the left eye and the right eye are attached to, for example, a spectacle type frame worn by the image observer 4.

This stereoscopic image display apparatus drives the left-eye image projector 2 and the right-eye image projector 3 alternately, so that the image light for the left eye and the right The image light for the eye is projected on the screen 1 alternately, and the light shutter element 5 for the left eye is opened when projecting the image light for the left eye and closed when projecting the image light for the right eye. By driving the optical shutter element 6 for the right eye so as to be closed when projecting the image light for the left eye and open when projecting the image light for the right eye, The image for the left eye projected on the screen 1 and the image for the right eye projected on the screen 1 by the right-eye image projector 3 are alternately observed by the left and right eyes of the image observer 4. The stereoscopic image obtained by synthesizing the image for the left eye and the image for the right eye is provided to the image observer 4. To identify.

[0008]

However, the above-mentioned conventional stereoscopic image display device allows the left-eye image to be observed by the left eye of the image observer 4 and the right-eye image to be observed by the left eye of the image observer 4. In order to perform this operation, the image light is projected alternately from the left-eye image projector 2 and the right-eye image projector 3, and the optical shutter elements 5 and 6 for the left and right eyes are alternately opened and closed in synchronization with the projection. Therefore, the drive control of the image projectors 2 and 3 and the optical shutter elements 5 and 6 is troublesome, and the left eye image observed by the left eye of the image observer 4 and the right eye Since the image for the right eye observed by the above is an intermittent image, there is a problem that a flicker occurs in the recognized three-dimensional image.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a three-dimensional image projection apparatus which does not require complicated driving control and allows an image observer to recognize a high-quality three-dimensional image without flicker. is there.

[0010]

A three-dimensional image display apparatus according to the present invention has a reflection axis and a transmission axis in directions substantially orthogonal to each other, and reflects incident light of a polarization component along the reflection axis.
A reflective polarizing screen that transmits incident light of a polarized component along the transmission axis, and a first that projects one of image light for the left eye and the right eye toward the front surface of the reflective polarizing screen. Image projection means, the second image projection means for projecting the other image light of the image light for the left eye and the image light for the right eye toward the back of the reflective polarizing screen, left and right of the image observer A first eyepiece polarizer arranged in front of one of the eyes with the transmission axis substantially parallel to the reflection axis of the reflective polarizing screen; and a transmission eye in front of the other eye of the image observer. A second eyepiece polarizer disposed so that its axis is substantially parallel to the transmission axis of the reflective polarizing screen, wherein the reflected light is projected toward the front surface of the reflective polarizing screen by the first image projection means; The one image reflected by the screen The light is observed by one eye of the image observer through the first eyepiece polarizer, and is projected by the second image projection means toward the back of the reflective polarizing screen. The other image light transmitted and emitted to the front surface is observed by the other eye of the image observer through the second eyepiece polarizer.

That is, this stereoscopic image display device has a reflection axis and a transmission axis in directions substantially orthogonal to each other as a screen on which image light is projected, and reflects incident light of a polarization component along the reflection axis. Then, using a reflective polarizing screen that transmits incident light of a polarization component along the transmission axis, one of image light for the left eye and the image light for the right eye is reflected by the first image projection unit. Projecting toward the front of the polarizing screen, projecting the other image light toward the back of the reflective polarizing screen by the second image projecting means, and using the first eyepiece in front of one eye of the image observer A polarizing plate is disposed with its transmission axis substantially parallel to the reflection axis of the reflective polarizing screen, and the second eyepiece polarizer is positioned with its transmission axis passing through the reflective polarizing screen in front of the other eye of the image observer. Almost parallel to the axis And the one image light reflected along the reflection axis of the reflective polarizing screen is projected by the first image projecting means toward the front surface of the reflective polarizing screen and reflected by the reflective polarizing screen. The polarized light component) is observed by one eye of an image observer through the first eyepiece polarizer, and is projected by the second image projection means toward the back surface of the reflective polarizing screen. The other image light (light of a polarization component along the transmission axis of the reflective polarizing screen) transmitted through the polarizing screen and emitted to the front thereof is transmitted to the other of the image observer via the second ocular polarizing plate. Is to be observed by the eyes of the subject.

According to this three-dimensional image display device, the first
Image light observed by one eye of the image observer through the eyepiece polarizer of the image light for the left eye and the right eye,
The first image projecting means projects only one image light projected toward the front surface of the reflective polarizing screen and reflected by the reflective polarizing screen.
The image light observed by the other eye of the image observer through the eyepiece polarizer of the left eye and the right eye image light, the second image projection means by the second image projection means of the reflective polarizing screen Only the other image light projected toward the back surface, transmitted through the reflective polarizing screen, and emitted to the front surface.

Therefore, the first image projection means and the second
Even if image light is continuously projected from both of the image projecting means, one image light projected by the first image projecting means is observed by one eye of an image observer, and the second
The other image light projected by the image projection means is observed by the other eye of the image observer, and the three-dimensional image in which these image lights are combined can be recognized by the image observer.

Therefore, according to this three-dimensional image display device, a conventional image light is projected alternately from two image projectors, and a light shutter element for the left eye and a light shutter element for the right eye are alternately opened and closed in synchronization with the image light. There is no need to perform troublesome drive control as in a stereoscopic image display device, and the image light is continuously projected from both the first image projecting means and the second image projecting means. A quality stereoscopic image can be recognized by an image observer.

[0015]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A three-dimensional image display device according to the present invention
As described above, as a screen for projecting image light, the screen has a reflection axis and a transmission axis in directions substantially orthogonal to each other, reflects incident light of a polarization component along the reflection axis, and reflects the light on the transmission axis. Using a reflective polarizing screen that transmits incident light of polarized light components along the same direction, and directs one of the image light for the left eye and the image light for the right eye toward the front surface of the reflective polarizing screen by the first image projection means. And project the other image light,
The second image projection means projects the light toward the back of the reflective polarizing screen, and the transmission axis of the first eyepiece polarizer is set substantially in front of one of the eyes of the image observer with the transmission axis of the first eyepiece polarizer. By arranging in parallel and in front of the other eye of the image observer, arranging a second eyepiece polarizer with its transmission axis substantially parallel to the transmission axis of the reflective polarizing screen, The one image light (image light composed of light of a polarization component along the reflection axis of the reflective polarizing screen) projected by the projection means toward the front surface of the reflective polarizing screen and reflected by the reflective polarizing screen, The image is observed by one eye of an image observer through the first eyepiece polarizer, and projected by the second image projection means toward the back of the reflective polarizing screen. The other of the image light emitted to the front surface passes through the lean (image light comprising light of the polarized component along the transmission axis of the reflective polarizing screen), the second
The eye observer can observe the image with the other eye of the image observer via the eyepiece polarizer, does not require troublesome drive control, and allows the image observer to recognize a good quality stereoscopic image without flicker. It is like that.

In the three-dimensional image display device of the present invention,
It is preferable to provide a light-transmissive imaging film for imaging the other image light projected toward the back surface of the reflective polarizing screen by the second image projection means on the back surface of the reflective polarizing screen. In this way, the other image light projected by the second image projection means is formed on the light-transmitting imaging film in a process of transmitting through the reflective polarizing screen and emitting to the front surface thereof. And the other image light is projected by the first image projection means toward the front surface of the reflective polarizing screen, and is observed in an observation state that is almost the same as the one image light reflected by the reflective polarizing screen. It can be observed by an image observer.

In this stereoscopic image display device,
The first image projecting means is configured to project the one image light as light of a polarization component along a reflection axis of the reflective polarizing screen toward the front surface of the reflective polarizing screen, and the second image projection Preferably, the means is configured to project the other image light toward the back surface of the reflective polarizing screen as light having a polarization component along the transmission axis of the reflective polarizing screen, and by doing so, The one image light projected by the first image projecting means toward the front surface of the reflective polarizing screen, reflected by the reflective polarizing screen, and directed to the rear surface of the reflective polarizing screen by the second image projecting means. And the other image light transmitted through the reflective polarizing screen and emitted to the front surface thereof is defined as a clearer and better-contrast image light. Was observed in the image viewer, it is possible to recognize the quality of the stereoscopic images.

Further, in this three-dimensional image display device, the first image projecting means projects the front surface of the reflective polarizing screen toward the front surface of the reflective polarizing screen, and reflects the light reflected by the reflective polarizing screen. The one image light and the other image light projected toward the back surface of the reflective polarizing screen by the second image projecting means and transmitted through the reflective polarizing screen and emitted to the front surface thereof are reflected by the reflected polarized light. It is preferable to provide a light condensing means for condensing light in a direction along the screen normal,
By doing so, the front luminance of the one image light and the other image light can be increased, and a brighter stereoscopic image can be recognized by the image observer.

[0019]

1 and 2 show an embodiment of the present invention. FIG. 1 is a plan view of a three-dimensional image display device, and FIG. 2 is a reflection polarizing screen of the three-dimensional image display device, and FIG.
FIG. 4 is a perspective view showing a polarizing plate included in the first and second image projection means, and directions of optical axes of first and second eyepiece polarizing plates.

As shown in FIGS. 1 and 2, the three-dimensional image display device of this embodiment has a reflective polarizing screen 10 on which image light is projected, and a first polarizer screen 10 disposed opposite to the front surface of the reflective polarizing screen 10. Image projection means 13 and a second
Image projection means 16 and first and second eyepiece polarizers 2 arranged in front of the left and right eyes of an image observer 19, respectively.
0, 21.

The reflective polarizing screen 10 is a screen made of a reflective polarizing plate, and has a reflection axis 10s and a transmission axis 10p in directions substantially orthogonal to each other.
0s, and reflects the incident light of the polarization component along the transmission axis 1
It has the property of transmitting incident light of a polarization component along 0p.

On the back of the reflective polarizing screen, there is provided a light-transmitting imaging film 11 for forming an image of the image light projected toward the back of the reflective polarizing screen 10 by the second image projection means 16. Is provided on the front surface of the reflective polarizing screen 10, and the image light projected by the first image projection means 13 toward the front surface of the reflective polarizing screen 10 and reflected by the reflective polarizing screen 10. And image light projected toward the back of the reflective polarizing screen 10 by the second image projecting means 16 and transmitted through the reflective polarizing screen 10 and emitted to the front thereof, by the method of the reflective polarizing screen 10. Light collecting means 12 for collecting light in a direction along the line is provided.

The light-transmitting imaging film 11 is formed of a white light-transmitting film, and the light condensing means 12 is provided on one of the front surface and the back surface of the transparent film, and has a fine surface. It is made of a lenticular lens film on which a lenticular lens is formed.

The first and second image projection means 13 and 16
Are, for example, image projectors 14 and 17 for enlarging and projecting the image light by a projection lens system using, for example, a tape-shaped moving image film, and polarizing plates 15 and 17 disposed on the emission side of the image projectors 14 and 17. It consists of 18.

Of the image projection means 13 and 16, the first image projection means 13 arranged opposite to the front surface of the reflective polarizing screen 10 is shifted in accordance with the difference in observation angle between the left eye and the right eye. One of the image light for the left eye and the image light for the right eye having, for example, the image light L for the left eye,
The polarization plate 15 projects the light s of the polarization component along the reflection axis 10 s of the reflection polarization screen 11 toward the front surface of the reflection polarization screen 10. This first image projection means (hereinafter, left) The polarizing plate 15 of the eye image projection means 13) is arranged with its transmission axis 15a substantially parallel to the reflection axis 10s of the reflective polarizing screen 10.

The second image projecting means 16 disposed opposite to the back surface of the reflective polarizing screen 10 is provided with the other image light of the left-eye image light and the right-eye image light, For example, the image light R for the right eye is projected by the polarizing plate 18 as light p of a polarized component along the transmission axis 10p of the reflective polarizing screen 10 toward the rear surface of the reflective polarizing screen 10. Polarizing plate 18 of second image projection means (hereinafter referred to as right-eye image projection means) 16
Are arranged with their transmission axes 18a substantially parallel to the transmission axis axis 10p of the reflective polarizing screen 10.

The left-eye image projection means 13 applies a left-eye image light L projected from the left-eye image projection means 13 to the reflection polarizing screen 10 at a predetermined position on the front surface of the reflection polarization screen 10. The right-eye image projection unit 16 is arranged to focus on the image so as to form an image at an enlargement ratio, and the right-eye image light R projected from the right-eye image projection unit 16 is projected onto the reflective polarizing screen 10. Light transmitting imaging film 11 provided on the back surface of the reflective polarizing screen 10
The focus adjustment is performed so that the image is formed at the same magnification as the image light L for the left eye, which forms an image on the front surface of the reflective polarizing screen 10.

Further, of the first and second eyepiece polarizers 20, 21, a first eyepiece polarizer (hereinafter referred to as a left-eye eyepiece polarizer) disposed in front of the left eye of the image observer 19 is provided. ) 20 is arranged with its transmission axis 29 a substantially parallel to the reflection axis 10 s of the reflective polarizing screen 10, and a second eyepiece polarizer (hereinafter, right eye) arranged in front of the right eye of the image observer 19. The eyepiece polarizer 21 is disposed with its transmission axis 21a substantially parallel to the transmission axis 10p of the reflective polarizing screen 10. The eyepiece polarizers 20 and 21 for the left and right eyes are, for example, image observers 19.
Is attached to the eyeglass frame.

The three-dimensional image display device is projected by the left-eye image projection means 13 toward the front surface of the reflective polarizing screen 10 as shown by a solid line in FIGS. 1 and 2, and reflected by the reflective polarizing screen 10. The left-eye image light L is observed by the left eye of the image observer 19 through the left-eye eyepiece polarizer 20, and the right-eye image projection unit 16 is used.
1 and FIG. 2, the image light R for the right eye projected toward the rear surface of the reflective polarizing screen 10 and transmitted through the reflective polarizing screen 10 and emitted to the front surface is reflected by the right eye. By allowing the image observer 19 to observe the image with the right eye via the eyepiece polarizer 21, the image observer 19 recognizes a stereoscopic image in which the left-eye image light L and the right-eye image light R are combined. It is intended to be.

In this three-dimensional image display apparatus, the left-eye image light L and the right-eye image light L emitted from the image projectors 14 and 17 of the left-eye image projection means 13 and the right-eye image projection means 16 are both used. As shown in FIG. 2, the image light includes both the light s of the polarization component along the reflection axis 10s of the reflection polarization screen 10 and the light p of the polarization component along the transmission axis 10p. R and L are the image projector 1
The light enters the polarizers 15 and 18 disposed on the exit side of the light-emitting devices 4 and 17, and is transmitted by the polarizers 15 and 18.
The light of a polarization component along an absorption axis (not shown) orthogonal to 8a is absorbed, and becomes light of a polarization component along the transmission axes 15a and 18a, on the front and back surfaces of the reflective polarizing screen 10. It is projected toward.

In this case, the polarizing plate 15 of the left-eye image projection means 13 is arranged with its transmission axis 15a substantially parallel to the reflection axis 10s of the reflective polarizing screen 10, and the polarization plate of the right-eye image projection means 16 is provided. The plate 18 has its transmission axis 18
a is arranged substantially parallel to the transmission axis 10p of the reflective polarizing screen 10, the left-eye image light L projected toward the front surface of the reflective polarizing screen 10 by the left-eye image projecting means 13 is As shown in FIG. 2, the light component s is a polarization component light s along the reflection axis 10 s of the reflective polarizing screen 10, and is projected onto the rear surface of the reflective polarizing screen 10 by the right-eye image projection unit 16. As shown in FIG. 2, the ophthalmic image light R is light p of a polarization component along the transmission axis 10p of the reflective polarizing screen 10.

The left-eye image light L projected toward the front surface of the reflective polarizing screen 10 by the left-eye image projecting means 13 has a reflection axis 10s of the reflective polarizing screen 10.
, The left-eye image light L is reflected by the reflective polarizing screen 10.

The right-eye image light R projected toward the rear surface of the reflective polarizing screen 10 by the right-eye image projecting means 16 is a light having a polarization component along the transmission axis 10p of the reflective polarizing screen 10. Because of s, the image light R for the right eye passes through the reflective polarizing screen 10 and is emitted to the front surface thereof.

In this embodiment, since the light-transmitting image forming film 11 is provided on the back of the reflective polarizing screen 10, the right-eye image projecting means 16 projects the light toward the back of the reflective polarizing screen 10. The right-eye image light R is transmitted through the reflective polarizing screen 10 and emitted to the front surface thereof, and forms an image on the light-transmitting image forming film 11,
The right-eye image light R formed on the light-transmitting image forming film 11 is
The light passes through the reflective polarizing screen 10 and is emitted to the front surface thereof.

In this embodiment, since the light condensing means 12 is provided on the front surface of the reflective polarizing screen 10, the light is projected toward the front surface of the reflective polarizing screen 10 by the left-eye image projecting means 13. The left-eye image light L reflected by the reflective polarizing screen 10 is projected by the right-eye image projecting means 16 toward the rear surface of the reflective polarizing screen 10, transmitted through the reflective polarizing screen 10, and the front surface thereof. Right image light R emitted to
And the reflective polarizing screen 1 as shown in FIG.
The light is condensed in a direction along the normal line of 0, and is emitted as light having high front luminance in front of the reflective polarizing screen 10.

In the composite image display device, the left eyepiece polarizing plate 2 disposed in front of the left eye of the image observer 19
0 and its transmission axis 29a
And the right-eye eyepiece polarizer 21 disposed in front of the right eye of the image observer 19 and disposed substantially parallel to the reflection axis 10s of the image observer 19.
Is arranged with its transmission axis 21a substantially parallel to the transmission axis 10p of the reflective polarizing screen 10.
0 is projected toward the front of the reflective polarizing screen 1.
The left-eye image light L reflected by 0 and the right-eye image projecting means 16 project the light toward the rear surface of the reflective polarizing screen 10, pass through the reflective polarizing screen 10, and exit to the front surface. Of the image light R for the right eye, the image light L for the left eye, which is the light s of the polarization component along the reflection axis 10s of the reflective polarizing screen 10, passes through the eyepiece polarizer 20 for the left eye to form an image. Observed by the left eye of the observer 19, the transmission axis 10p of the reflective polarizing screen 10
The image light R for the right eye, which is the light p of the polarization component along, is transmitted through the eyepiece polarizer 21 for the right eye and is observed by the right eye of the image observer 19.

That is, this stereoscopic image display device has a reflection axis 10s and a transmission axis 10p in directions substantially orthogonal to each other as a screen on which image light is projected, and the polarization component incident along the reflection axis 10s is incident. Using the reflective polarizing screen 10 that reflects light s and transmits the incident light p of the polarization component along the transmission axis 10p, the image light for the left eye among the image lights L and R for the left and right eyes R is projected by the left-eye image projection means 13 toward the front surface of the reflective polarizing screen 10, and the right-eye image light R is projected by the right-eye image projection means 16 toward the rear surface of the reflective polarizing screen 10. At the same time, the eyepiece polarizer 20 for the left eye is set in front of the left eye of the image observer 19 with the transmission axis 20 a of the reflective polarizing screen 1.
0 is disposed substantially parallel to the reflection axis 10s, and the right eyepiece polarizer 21 is disposed in front of the right eye of the image observer 19 with the transmission axis 21a of the transmission axis 10p of the reflection polarization screen 10.
Are arranged substantially in parallel with each other, the left-eye image projection means 13 projects the light toward the front surface of the reflective polarizing screen 10 and is reflected by the reflective polarizing screen 10 to produce image light for the left eye (the reflective polarizing screen 10). Is observed by the left eye of the image observer 19 through the eyepiece polarizing plate 20 for the left eye, and the reflected polarizing screen 10 is projected by the right-eye image projection means 16. The image light for the right eye (light p of the polarization component along the transmission axis 10p of the reflective polarizing screen 10) projected toward the rear surface of the reflective polarizing screen 10 and emitted to the front surface of the reflective polarizing screen 10 The image is observed by the right eye of the image observer 19 via the eyepiece polarizing plate 21 for the right eye.

According to this stereoscopic image display apparatus, the image light observed by the left eye of the image observer 19 via the eyepiece polarizer 20 for the left eye is divided into the image lights L and R for the left and right eyes. Of the reflective polarizing screen 1 by the left-eye image projection means 13
0 is projected toward the front of the reflective polarizing screen 1.
0 is only the left-eye image light L reflected by 0, and
The image light observed by the right eye of the image observer 19 via the right-eye eyepiece polarizer 21 is reflected by the right-eye image projection means 16 of the left-eye and right-eye image lights R and L. Only the right-eye image light R projected onto the rear surface of the polarizing screen 10 and transmitted through the reflective polarizing screen 10 and emitted to the front surface thereof.

Therefore, even if the image light L and R are continuously projected from both the left-eye image projection means 13 and the right-eye image projection means 16, the left-eye image projected by the left-eye image projection means 13 The light L is observed by the left eye of the image observer 19,
Right-eye image light R projected by right-eye image projection means 16
Can be observed by the right eye of the image observer 19, and the image observer 19 can recognize the stereoscopic image in which these image lights are combined.

Therefore, according to this three-dimensional image display device, a conventional image light is alternately projected from two image projectors, and the optical shutter elements for the left and right eyes are alternately opened and closed in synchronization with the image light. There is no need to perform troublesome drive control as in a stereoscopic image display device.
3 and the right-eye image projection means 16 continuously project image light, so that the image observer 19 can recognize a stereoscopic image of good quality without flicker.

Further, in the above embodiment, the right-eye image light R projected by the right-eye image projection means 16 toward the rear surface of the reflective polarizing screen 10 is formed on the rear surface of the reflective polarizing screen 10. Light-transmitting imaging film 11
Is provided, the right-eye image light R projected by the right-eye image projection means 16 is transmitted to the reflective polarizing screen 1.
In the process of transmitting the light through 0 and emitting the light to the front surface thereof, an image is formed on the light-transmitting imaging film 11, and the image light R for the right eye is directed toward the front surface of the reflective polarizing screen 10 by the left-eye image projection means 13. The image observer 19 can be observed in an observation state that is almost the same as the image light L for the left eye projected and reflected by the reflective polarizing screen 10.

In the above embodiment, the left-eye image projection means 13 is provided with the polarizing plate 15 on the emission side of the image projector 14, and the left-eye image light L is transmitted to the reflection axis 10s of the reflection polarization screen 10. The right-eye image projecting means is configured to project a polarizing plate 18 on the emission side of the image projector 18 as a light component s along the polarized light component projected along the front surface of the reflective polarizing screen 10.
And the right-eye image light R is projected toward the rear surface of the reflective polarizing screen 10 as light p of a polarization component along the transmission axis 10p of the reflective polarizing screen 10, so that the left-eye image projection is performed. The image light L for the left eye projected onto the front surface of the reflective polarizing screen 10 by the means 13 and reflected by the reflective polarizing screen 10, and the reflective polarizing screen 10 by the right-eye image projecting means 16.
Of the reflective polarizing screen 10
And the right-eye image light R emitted to the front surface of the image observer 1 as a clearer and better-contrast image light.
9 can be observed and a high-quality stereoscopic image can be recognized.

Further, in the above embodiment, the left-eye image projecting means 13 projects the front surface of the reflective polarizing screen 10 toward the front surface of the reflective polarizing screen 10,
The left-eye image light R reflected by the reflective polarizing screen 10 is projected by the right-eye image projecting means 16 toward the rear surface of the reflective polarizing screen 10 and transmitted through the reflective polarizing screen 10 to the front surface. Since the condensing means 12 for condensing the emitted right-eye image light R in a direction along the normal line of the reflective polarizing screen 10 is provided, the left-eye image light L and the right-eye image light R are provided. By increasing the front luminance of the image light R, the image observer 19 can recognize a brighter stereoscopic image.

In the above embodiment, the left-eye image projecting means 13 is arranged to face the front surface of the reflective polarizing screen 10 and the right-eye image projecting means 16 is placed on the reflective polarizing screen 1.
Although it is arranged facing the back of 0, on the contrary,
The right-eye image projection means 16 is connected to the reflective polarizing screen 1.
0, and the left-eye image projection means 13 may be arranged to face the rear surface of the reflective polarizing screen 10.

In this case, the polarizing plate 18 of the right-eye image projection means 16 and the eyepiece polarizing plate 21 for the right eye are set so that their transmission axes 18a, 21a are substantially parallel to the reflection axis 10s of the reflection polarizing screen 10. The polarizing plate 15 of the left-eye image projection means 13 and the ocular polarizing plate 20 for the left eye are arranged such that their transmission axes 15a and 20a are substantially parallel to the transmission axis 10p of the reflective polarizing screen 10. I just need.

The left-eye image projection means 13 of the above embodiment
And a right-eye image projecting means 16 that enlarges and projects the image light using a tape-like moving image film,
17, the left-eye image projection means 13
The right-eye image projecting means 16 enlarges and projects still image light using a slide film, displays an image on an image display such as a liquid crystal display element or a CRT (CRT), and enlarges and projects the image light. In the case where a liquid crystal display device provided with a polarizing plate is used as the image display, the polarizing plates 15 and 18 disposed on the emission sides of the image projectors 14 and 17 in the above embodiment are replaced with the liquid crystal display device. What is necessary is just to also use the polarizing plate of an emission surface side.

Further, in the above-described embodiment, the first image projecting means (the left-eye image projecting means 13 in the above-described embodiment) is used to apply one image light (the left-eye image light L in the above-described embodiment) to the reflected polarized light. It is configured to project the light s of the polarization component along the reflection axis 10s of the screen 10 toward the front surface of the reflection polarization screen 10, and the second image projection means (the right-eye image projection means 16 in the above embodiment) The other image light (the right-eye image light R in the above embodiment) is transmitted to the reflective polarizing screen 10.
Is projected toward the back of the reflective polarizing screen 10 as light p of a polarized component along the transmission axis 10p of the reflective polarizing screen. The first image projecting means and the second image projecting means A non-polarized image light that includes both the polarized light component s along the reflection axis 10s and the polarized light component p along the transmission axis 10p may be projected.

Also in this case, of the one image light projected toward the front surface of the reflective polarizing screen 10 by the first image projecting means, the light of the polarization component along the reflection axis 10s of the reflective polarizing screen 10 Is reflected by the reflective polarizing screen 10, and along the transmission axis 10p of the reflective polarizing screen 10, of the other image light projected by the second image projection means toward the back of the reflective polarizing screen 10. Since the light of the polarized light component is transmitted through the reflective polarizing screen 10 and emitted to the front surface thereof, the image light observed by one eye of the image observer 19 via the first ocular polarizing plate 20 is the first light. Is projected toward the front surface of the reflective polarizing screen 10 by the image projecting means, and only one image light reflected by the reflective polarizing screen 10 is provided. The image light observed by the other eye of the image observer 19 via the second eyepiece polarizer 21 is projected by the second image projection means toward the back of the reflective polarizing screen 10, and this reflective polarizing screen is 10 is only the other image light that has passed through and emitted to the front surface.

In the above embodiment, the light for forming the other image light projected on the back surface of the reflective polarizing screen 10 toward the back surface of the reflective polarizing screen 10 by the second image projection means is formed on the back surface of the reflective polarizing screen 10. Although the transmission imaging film 11 is provided, the light transmission imaging film 11 may be omitted, and in this case, the second image projection unit may be provided to Focus adjustment is performed such that the other image light projected from the second image projection means is formed on the front surface of the reflective polarizing screen 10 at the same magnification as the one image light formed on the front surface of the reflective polarizing screen 10. And place them.

Further, in the above embodiment, the first image projecting means projects the front surface of the reflective polarizing screen 10 toward the front surface of the reflective polarizing screen 10,
One image light reflected by the reflective polarizing screen 10 and the other image light projected by the second image projecting means toward the back surface of the reflective polarizing screen 10, transmitted through the reflective polarizing screen 10, and emitted to the front surface thereof The light condensing means 12 is provided for condensing the image light in the direction along the normal line of the reflective polarizing screen 10, but the light condensing means 12 may be omitted.

[0051]

The three-dimensional image display device of the present invention has a reflection axis and a transmission axis in directions substantially orthogonal to each other as a screen for projecting image light, and the polarization component is incident along the reflection axis. A first polarizing unit that reflects light and transmits one of the left and right image light beams to a first image projection unit using a reflective polarizing screen that transmits incident light of a polarization component along the transmission axis; Is projected toward the front surface of the reflective polarizing screen, and the other image light is projected toward the back surface of the reflective polarizing screen by the second image projection means, and the second image light is projected in front of one eye of an image observer. The eyepiece polarizer is disposed so that its transmission axis is substantially parallel to the reflection axis of the reflective polarizing screen, and the second eyepiece is placed in front of the other eye of the image observer.
By disposing the eyepiece polarizer with its transmission axis substantially parallel to the transmission axis of the reflective polarizing screen,
The one image light (image light composed of light of a polarization component along the reflection axis of the reflective polarizing screen) projected onto the front surface of the reflective polarizing screen by the image projecting means and reflected by the reflective polarizing screen. The first
Is observed by one eye of an image observer through the eyepiece polarizer, projected by the second image projection means toward the back of the reflective polarizing screen, transmitted through the reflective polarizing screen, and emitted to the front. The other image light (image light composed of light of a polarization component along the transmission axis of the reflective polarizing screen) is observed by the other eye of the image observer via the second eyepiece polarizing plate. This eliminates the need for troublesome drive control and allows the image observer to recognize a good-quality stereoscopic image without flicker.

In the three-dimensional image display device of the present invention,
It is preferable to provide a light-transmissive imaging film for imaging the other image light projected toward the back surface of the reflective polarizing screen by the second image projection means on the back surface of the reflective polarizing screen. In this way, the other image light projected by the second image projection means is formed on the light-transmitting imaging film in a process of transmitting through the reflective polarizing screen and emitting to the front surface thereof. And the other image light is projected by the first image projection means toward the front surface of the reflective polarizing screen, and is observed in an observation state that is almost the same as the one image light reflected by the reflective polarizing screen. It can be observed by an image observer.

In this three-dimensional image display device,
The first image projecting means is configured to project the one image light as light of a polarization component along a reflection axis of the reflective polarizing screen toward the front surface of the reflective polarizing screen, and the second image projection Preferably, the means is configured to project the other image light toward the back surface of the reflective polarizing screen as light having a polarization component along the transmission axis of the reflective polarizing screen, and by doing so, The one image light projected by the first image projecting means toward the front surface of the reflective polarizing screen, reflected by the reflective polarizing screen, and directed to the rear surface of the reflective polarizing screen by the second image projecting means. And the other image light transmitted through the reflective polarizing screen and emitted to the front surface thereof is defined as a clearer and better-contrast image light. Was observed in the image viewer, it is possible to recognize the quality of the stereoscopic images.

Further, in this stereoscopic image display device, the first image projecting means projects the front surface of the reflective polarizing screen toward the front surface of the reflective polarizing screen, and reflects the light reflected by the reflective polarizing screen. The one image light and the other image light projected toward the back surface of the reflective polarizing screen by the second image projecting means and transmitted through the reflective polarizing screen and emitted to the front surface thereof are reflected by the reflected polarized light. It is preferable to provide a light condensing means for condensing light in a direction along the screen normal,
By doing so, the front luminance of the one image light and the other image light can be increased, and a brighter stereoscopic image can be recognized by the image observer.

[Brief description of the drawings]

FIG. 1 is a plan view of a stereoscopic image display device according to an embodiment of the present invention.

FIG. 2 is a perspective view showing a reflective polarizing screen in the stereoscopic image display device, a polarizing plate included in first and second image projection means, and directions of optical axes of first and second eyepiece polarizing plates.

FIG. 3 is a plan view of a conventional stereoscopic image display device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 ... Reflection polarizing screen 10s ... Reflection axis 10p ... Transmission axis 11 ... Light transmitting imaging film 12 ... Condensing means 13,16 ... Image projecting means 14,17 ... Image projector 15,18 ... Polarizing plate 15a, 18a ... Transmission axis 19: Image observer 20, 21: Eyepiece polarizing plate 20a, 21a: Transmission axis 20s: Reflection axis 20p: Transmission axis L: Image light for left eye R: Image light for right eye

Claims (4)

[Claims] A reflection axis and a transmission axis extending in directions substantially orthogonal to each other, for reflecting incident light of a polarization component along the reflection axis and transmitting incident light of a polarization component along the transmission axis; A reflective polarizing screen, first image projecting means for projecting one of image light for the left eye and the right eye toward the front surface of the reflective polarizing screen, and for the left eye and the right eye Second image projection means for projecting the other image light of the image light toward the back of the reflective polarizing screen; and a transmission axis in front of one of the left and right eyes of the image observer. A first eyepiece polarizer disposed substantially parallel to the reflection axis of the reflective polarizing screen, and a transmission axis substantially parallel to the transmission axis of the reflective polarizing screen before the other eye of the image observer. Second placed
An eyepiece polarizer, wherein the one image light projected toward the front surface of the reflective polarizing screen by the first image projecting means and reflected by the reflective polarizing screen is used as the first eyepiece polarizer. Through one of the eyes of the image observer,
The other image light projected toward the rear surface of the reflective polarizing screen by the second image projecting means and transmitted through the reflective polarizing screen and emitted to the front surface thereof is transmitted through the second ocular polarizing plate. A stereoscopic image display device characterized in that the image is observed by the other eye of the image observer. 2. A light-transmitting image-forming film for forming an image of the other image projected by the second image projection means toward the back of the reflective polarizing screen is provided on the back of the reflective polarizing screen. The three-dimensional image display device according to claim 1, wherein: 3. The first image projection means projects one image light as light of a polarization component along a reflection axis of the reflection polarization screen toward the front surface of the reflection polarization screen, and the second image projection means. And projecting the other image light as light having a polarization component along the transmission axis of the reflective polarizing screen toward the rear surface of the reflective polarizing screen.
3. The stereoscopic image display device according to 1. 4. An image light projected onto a front surface of a reflective polarizing screen by a first image projecting means toward the front surface of the reflective polarizing screen, and one image light reflected by the reflective polarizing screen and a second image projection. The other image light projected toward the rear surface of the reflective polarizing screen by the means and transmitted through the reflective polarizing screen and emitted to the front surface is focused in a direction along the normal line of the reflective polarizing screen. The three-dimensional image display device according to claim 1, further comprising a light condensing unit that performs light collection.