JPH0573116B2 - - Google Patents

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention relates to a so-called polarized projection stereoscopic television receiver (hereinafter referred to as "projection stereoscopic TV") that is observed by an observer wearing polarized glasses. Regarding.

[Summary of the invention]

The present invention provides a so-called polarized projection 3D TV that uses a polarizing beam splitter as a light source, a polarizer and an analyzer, and rotates the plane of polarization for each pixel portion based on a video signal, without using a projection cathode ray tube. By using a liquid crystal device or the like that performs this, it is possible to obtain particularly high-brightness images.

[Conventional technology]

As a polarized projection type 3D TV, the one shown in FIG. 3 has been proposed. In the figure, 1L and 1R are projection type cathode ray tubes for generating a left eye image S _L and a right eye image S _R , respectively. The image light from the left eye image S _L generated by the cathode ray tube 1L is projected onto the screen 4 via the projection lens 2L and the polarizing filter 3L, and the image light from the right eye image S _R generated by the cathode ray tube 1R is The image light is projected onto the screen 4 via the projection lens 2R and polarizing filter 3R. In this case, the polarizing filters 3L and 3R have polarization planes that are perpendicular to each other. Therefore, when an observer observes the screen 4 while wearing orthogonal polarizing filter glasses having polarization planes corresponding to the polarizing filters 3L and 3R, so-called polarized glasses, the left eye image and the right eye image are displayed with the left eye and the right eye, respectively. Eye images can be seen and stereoscopic images can be perceived.

[Problems to be Solved by the Invention] However, according to such a projection type 3D TV, the image light from the images S _L and S _R passes through the polarizing filter 3.
The light is projected onto the screen 4 via the cathode ray tubes 1L and 3R, and the light output is significantly reduced due to the presence of the polarizing filters 3L and 3R. Lens 2L,
It was necessary to increase the size of the 2R, etc., and there was a problem that the entire device became large. In addition, in the case of colorization, red, green,
Six tubes, two tubes for each blue color, are required, and along with this, a lens system is also required for each, resulting in the problem of increasing the size of the entire device.

In view of these points, the present invention makes it possible to obtain a compact and high-luminance device, and also to prevent the device from becoming too large when it is to be colored.

[Means for solving problems]

The present invention is constructed without using a projection cathode ray tube. That is, the present invention provides a light source such as a xenon arc lamp 5, a first polarizing beam splitter 8 constituting a polarizer to which light from the light source is supplied, and a light source obtained from the first polarizing beam splitter 8. a left-eye image liquid crystal device 10L, which is supplied with first polarized light such as P-polarized light _P , and rotates the plane of polarization for each pixel portion based on a left-eye video signal;
The second beam obtained from the first polarizing beam splitter 8
A right-eye image liquid crystal device 10R is supplied with polarized light, for example, S-polarized light _S , and rotates the plane of polarization for each pixel portion based on a right-eye video signal, and the liquid crystal device 10
A second polarizing beam splitter 11 constituting an analyzer to which light from L and 10R is supplied;
and a projection lens 14 that projects the light from the polarizing beam splitter 11 onto a screen 15.

[Effect]

The first and second
Since the polarization plane of the polarized light is rotated for each pixel portion, from the second polarized beam splitter 11,
Image light _S ^* of the left eye image and image light _P ^* of the right eye image are obtained by polarized light having planes of polarization perpendicular to each other,
These are projected onto the screen 15 by the projection lens 14. Therefore, when an observer observes the screen 15 while wearing polarized glasses that are orthogonal on the left and right sides, the left eye image and the right eye image can be seen with the left eye and the right eye, respectively, and a stereoscopic image is perceived. .

[Embodiment] Hereinafter, an embodiment of the present invention will be described with reference to FIG.

In the figure, 5 is a xenon lamp constituting a light source, and 6 is an ellipsoidal mirror. The light from this xenon lamp 5 is made into parallel light by a collimating concave lens 7 and then supplied to a polarizing beam splitter 8.
P component polarized light _P traveling straight and S component polarized light _S reflecting
It is separated into

After the P component polarized light _P is reflected by the mirror 9L,
The light is supplied to the transmissive liquid crystal device 10L, and during the process of passing through the liquid crystal device 10L, the plane of polarization is rotated based on the left eye video signal for each pixel portion located in a matrix. This liquid crystal device 10L is
For example, it is constructed of twisted nematic liquid crystal and utilizes the rotation of the plane of polarization due to its twist effect. That is, transparent electrodes are arranged on the entire surface of one surface with the liquid crystal in between, and transparent pixel electrodes are arranged in a matrix (for example, 512 pixels) on the other surface corresponding to each pixel.
x512), and is configured such that pixel signals sampled and formed from the left eye video signal are supplied to pixel electrodes corresponding to each pixel, respectively.

The polarized light, which is obtained by passing through the liquid crystal device 10L and whose plane of polarization has been rotated for each pixel portion, is supplied to the polarizing beam splitter 11. Then, the S component polarized light _S ^* generated by the rotation of the polarization plane is reflected and output to the field lens 12 side. This polarized light
_S ^* is image light that is to form a left-eye image with brightness and darkness modulation for each pixel portion. This polarized light _S ^* is supplied to a zoom projection lens 14 via a field lens 12 and a reduction lens 13, and is then applied to a screen 15.
projected onto the top.

In addition, S obtained from the polarizing beam splitter 8
After the component polarized light _S is reflected by the mirror 9R, it is supplied to the transmissive liquid crystal device 10R, and in the process of passing through the liquid crystal device 10R, the component polarized light S is transmitted to each pixel portion located in a matrix based on the right eye video signal. The plane of polarization is rotated. This liquid crystal device 10R is also configured in the same manner as the liquid crystal device 10L described above, and the drive signal is a right eye video signal.

The polarized light, which is obtained by passing through the liquid crystal device 10R and whose plane of polarization has been rotated for each pixel portion, is supplied to the polarizing beam splitter 11. Then, the P component polarized light _P ^* generated by the rotation of the polarization plane travels straight and is output to the field lens 12 side. Similarly to this polarized light _P ^* , it is supplied to the zoom projection lens 14 via the field lens 12 and the reduction lens 13, and is projected onto the screen 15 in an overlapping manner.

The present example is configured as described above, and a left eye image and a right eye image using polarized lights _S ^* and _P ^* having mutually orthogonal polarization planes are displayed on the screen 15 in an overlapping manner. Therefore, when an observer observes the screen 15 while wearing right and left polarized glasses, the viewer can see the left eye image and the right eye image with the left and right eyes, respectively, and perceive a stereoscopic image. I can do it.

According to this example, there is no significant drop in the light output compared to the example in FIG. The brightness of the displayed left-eye image and right-eye image can be easily increased, and compared to the example shown in FIG. 3, a smaller size and higher brightness can be obtained. In addition, according to this example, even if the projection lens system is used in common for the left and right sides and six liquid crystal devices are used, two each for red, green, and blue, to achieve color display, it is not necessary to increase the size accordingly. It can be configured without Furthermore, since the liquid crystal devices 10L and 10R are used according to this example, even when the liquid crystal devices 10L and 10R are driven alternately for each field, these liquid crystal devices 10L and 10R are used.
The memory function of L and 10R has the advantage of reducing flicker.

Next, FIG. 2 shows another embodiment of the present invention, in which a reflective liquid crystal device is used.
In FIG. 2, parts corresponding to those in FIG. 1 are designated by the same reference numerals, and detailed explanation thereof will be omitted.

In the figure, light from a xenon lamp 5 passes through a parallelizing concave lens 7 to a polarizing beam splitter 1.
6, and is separated into P-component polarized light _P ^* , which travels straight, and S-component polarized light _S ^* , which is reflected.

The P component polarized light _P ^* is supplied to a reflective liquid crystal device 17L, and in the process of being reflected by this liquid crystal device 17L, the plane of polarization is rotated based on the left eye video signal for each pixel portion located in a matrix. will be done.
The liquid crystal device 17L is composed of, for example, a 90° twisted nematic liquid crystal, and utilizes the rotation of the plane of polarization due to its birefringence effect. That is, transparent electrodes are arranged on the entire surface of one surface (the surface where light enters) with the liquid crystal in between, and pixel electrodes are formed in a matrix on the other surface corresponding to each pixel, and each pixel electrode For example, aluminum is deposited on the mirror, and it also serves as a reflecting mirror. The pixel electrode is configured such that a pixel signal sampled from the left eye video signal is supplied to the pixel electrode.

The polarized light obtained by reflection from the liquid crystal device 17L and whose plane of polarization has been rotated for each pixel portion is supplied to the polarizing beam splitter 16 again. and,
The S component polarized light _S ^* generated by the rotation of the polarization plane is reflected and output to the field lens 12 side. This polarized light _S ^* is image light that is to form a left eye image in which brightness and darkness are modulated for each pixel portion. This polarized light
_S ^* is supplied to a zoom projection lens 14 via a field lens 12 and a reduction lens 13, and is projected onto a screen 15.

Further, the S component polarized light _S ^* obtained from the polarizing beam splitter 16 is supplied to a reflective liquid crystal device 17R, and in the process of being reflected by this liquid crystal device 17R, the right Rotation of the plane of polarization is performed based on the eye image signal.
This liquid crystal device 17R is also the liquid crystal device 17L mentioned above.
It is configured in the same way as the above, and the drive signal is a right eye video signal.

The polarized light obtained by reflection from the liquid crystal device 17R and whose plane of polarization has been rotated for each pixel portion is supplied to the polarizing beam splitter 16 again. Then, the P component polarized light _P ^* generated by the rotation of the polarization plane travels straight and is output to the field lens 12 side. This polarized light _P ^* is image light that is to form a right eye image in which brightness and darkness are modulated for each pixel portion. This polarized light _P ^* is supplied to the zoom projection lens 14 via the field lens 12 and the reduction lens 13,
It is projected onto the screen 15.

The example in Fig. 2 is configured as described above, and like the example in Fig. 1, polarized light _S ^* having mutually orthogonal polarization planes is
A left eye image and a right eye image by P ^* and _P * are displayed superimposed on the screen 15, and when an observer observes the screen 15 while wearing right and left polarized glasses orthogonal to each other, a stereoscopic image can be perceived.

Also in this example in FIG. 2, the liquid crystal devices 17L, 1
7R or the like, and can obtain the same effects as the above-mentioned example in FIG. 1.

[Effects of the Invention] According to the present invention as described above, there is no significant drop in light output compared to those using conventional polarizing filters, and the brightness of the displayed image can be easily increased by increasing the brightness of the light source. It is possible to obtain a compact and high-brightness device. In addition, the projection lens system can be used commonly for both the left and right sides, and it can be constructed in color without increasing the size.
Furthermore, since a liquid crystal device is used, even when the left and right sides are driven alternately, flicker is reduced due to its memory function.

[Brief explanation of drawings]

FIG. 1 is a configuration diagram showing one embodiment of the present invention, and FIG.
The figure is a block diagram showing another embodiment of the present invention, and FIG. 3 is a block diagram showing a conventional example. 5 is a xenon lamp, 8 and 11 are polarizing beam splitters, 10L and 10R are liquid crystal devices, 14 is a zoom projection lens, and 15 is a screen.

Claims (1)

[Scope of Claims] 1. A light source, a first polarizing beam splitter constituting a polarizer, and a left-eye image liquid crystal device that rotates the plane of polarization for each pixel based on a left-eye video signal.
A right-eye image liquid crystal device that rotates the plane of polarization for each pixel based on a right-eye video signal, a second polarizing beam splitter constituting an analyzer, and a projection lens; is supplied to the first polarizing beam splitter, the first polarized light obtained from the first polarizing beam splitter is supplied to the left eye image liquid crystal device, and the light obtained from this liquid crystal device is supplied to the first polarizing beam splitter. projected onto the screen via the second polarized beam splitter and the projection lens, and obtained from the first polarized beam splitter;
A second polarized light having a plane of polarization perpendicular to the first polarized light is supplied to the right eye image liquid crystal device, and light obtained from the liquid crystal device is transmitted through the second polarized beam splitter and the projection lens. A projection type stereoscopic television receiver characterized in that the image is projected onto a screen and the image on the screen is observed through polarized glasses.