JP2010160216A - Video display system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a video display system capable of switching and displaying videos projected from a plurality of video projectors. <P>SOLUTION: The video display system includes (a) a linearly polarized light selective screen that has, in a plane, a scattering axis where scattering is the largest to linearly polarized light, and a transmission axis where scattering is the smallest to the linearly polarized light, (b) a first video projector that projects a video by polarized light in a first polarization direction to the linearly polarized light selective screen, (c) a second video projector that projects a video by polarized light in a second polarization direction perpendicular to the first polarization direction to the linearly polarized light selective screen, and (d) a switching device that switches directions so that either of the first and second polarization directions may be a scattering axis direction of the linearly polarized light selective screen. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a video display system having a video projection screen and a video projector.

  Video projectors (projection type display devices) are increasing in demand because they can realize a large screen display at a small size and at a lower cost than direct view type display devices. In particular, a video projector using a liquid crystal element as a two-dimensional optical switch, that is, a liquid crystal projector, unlike a video projector using a CRT projection tube, is capable of high-definition display without blurring to the periphery of the screen by a dod matrix display. Therefore, it is expected as a favorite of high-resolution digital television.

  Conventionally, as a screen on which an image is projected by the image projector, a white screen that totally reflects the projection light from the image projector has been used. However, in recent years, a polarization-selective screen that selectively reflects only a specific polarized light has been proposed in order to improve the contrast of an image projector that projects an image with polarized light, particularly a reflective screen used with a liquid crystal projector. In such a polarization-selective screen, it is displayed by reflecting / scattering the polarized light projected from the image projector and transmitting and / or absorbing half of the polarized light in a different direction, that is, half of the ambient light. The contrast of the video is improved (Patent Documents 1 to 5).

  In this regard, for example, Patent Document 5 discloses a linearly polarized light selective screen having in the plane a scattering axis with the largest scattering with respect to the linearly polarized light and a transmission axis with the smallest scattering with respect to the linearly polarized light. . Here, this linearly polarized light selective screen includes an oriented film containing polymer fine particles in a polymer matrix, and these polymer matrix and polymer fine particles have a specific refractive index anisotropy. ing.

JP-A-5-107660 JP 2005-17751 A Special Table 2002-540445 JP 2005-526283-A International Publication WO2006 / 009293

  One object of the present invention relates to a video display system capable of switching and displaying videos projected from a plurality of video projectors. Other objects and advantages of the present invention will become apparent from the following description.

  The present invention is as follows:

<1> (a) a linearly polarized light selective screen having in-plane a scattering axis with the largest scattering with respect to the linearly polarized light and a transmission axis with the smallest scattering with respect to the linearly polarized light;
(B) a first image projector for projecting an image with polarized light in a first polarization direction on the linearly polarized light selective screen;
(C) a second image projector for projecting an image with polarized light having a second polarization direction perpendicular to the first polarization direction with respect to the linearly polarized light selective screen; and (d) the first and second images. A switching device that switches so that any one of the polarization directions of the linearly polarized light selective screen is the scattering axis direction of the linearly polarized light selective screen,
A video display system.
<2> The switching device rotates the linearly polarized light selective screen to switch the scattering axis of the linearly polarized light selective screen so as to be parallel to one of the first and second polarization directions. The video display system according to <1>, wherein the video display system is a screen rotation device.
<3> The video display system according to <2>, wherein the screen rotation device rotates the linearly polarized light selective screen around an axis in a normal direction of the linearly polarized light selective screen.
<4> The video display system according to <2>, wherein the screen rotating device rotates the linearly polarized light selective screen around an axis in a plane direction of the linearly polarized light selective screen.
<5> The switching device rotates the polarized light in the first and second polarization directions around a projection direction axis of each polarization, and any one of the first and second polarization directions is The video display system according to <1>, wherein the polarization rotation device is switched so as to be parallel to the scattering axis of the linearly polarized light selective screen.
<6> The video display according to <5>, wherein the polarization rotation device rotates the polarized light in the first and second polarization directions around a projection direction axis of each polarization by a retardation film. system.
<7> The polarization rotation device rotates the first and second image projectors themselves to rotate the polarized light in the first and second polarization directions around the projection direction axis of each polarization. The video display system according to item <5>.

  According to the video display system of the present invention, videos projected from a plurality of video projectors, for example, videos projected from the first and second video projectors can be switched and displayed on the screen. Therefore, for example, the video projected from the first and second video projectors can be switched quickly and alternately, and the synthesized video of the video projected from the first and second video projectors can be perceived by the observer. Can be switched relatively slowly to allow the viewer to perceive the images projected from the first and second image projectors, respectively.

  Hereinafter, the video display system of the present invention will be described with reference to the drawings. However, the video display system of the present invention is not limited by the description of these drawings.

  The video display system 100 of the present invention shown in FIG. 1 includes (a) a linearly polarized light selective screen 10, (b) a first video projector 11, (c) a second video projector 21, and (d) a switching device. Have.

<(A) Linearly polarized light selective screen>
The linearly polarized light selective screen 10 used in the image display system 100 of FIG. 1 has in its plane a scattering axis that causes the largest scattering with respect to the linearly polarized light and a transmission axis that causes the smallest scattering with respect to the linearly polarized light. This linearly polarized light selective screen comprises, for example, an oriented film containing polymer fine particles in a polymer matrix having a specific refractive index anisotropy, as shown in Patent Document 5.

  In this linearly polarized light selective screen, the screen itself can be made self-supporting, or the screen can be suspended. In the case where the linearly polarized light selective screen itself is self-supporting, for example, a transparent base material, a formwork or the like can be provided on the screen. As the transparent substrate, an optically transparent organic transparent substrate such as an acrylic resin, an inorganic transparent substrate such as a glass substrate, or the like can be used.

  Note that the linearly polarized light selective screen usually allows an image projected from the image projector to the screen to be observed from either the same side or the opposite side of the image projector with respect to the screen. However, in relation to the present invention, the “reflective linearly polarized light selective screen” refers to the image projected from the image projector on the same side as the image projector (ie, the viewer A side in FIG. 1) with respect to the screen. It shall mean a linearly polarized light selective screen having properties suitable for viewing. Further, regarding the present invention, the “transmission type linearly polarized light selective screen” refers to an image projected from the image projector on the side opposite to the image projector with respect to the screen (that is, the viewer B side in FIG. 1). It shall mean a linearly polarized light selective screen having properties suitable for viewing from.

For example, the reflective linear polarization selective screen is a linear polarization selective screen that satisfies the following equations (1) and (2):
2 <TT _trans / TT _scat or 3 <TT _trans / TT _scat (1)
TT <60% or TT <50% (2)
(TT _trans : total light transmittance in the transmission axis direction TT _scat : total light transmittance in the scattering axis direction TT: total light transmittance).

For example, a transmissive linearly polarized light selective screen is a linearly polarized light selective screen that satisfies the following equations (3) and (4):
1 ≦ TT _trans / TT _scat ≦ 2, or 1 ≦ TT _trans / TT _scat ≦ 1.5 (3)
60% ≦ TT or 70% ≦ TT (4)
(TT _trans : total light transmittance in the transmission axis direction TT _scat : total light transmittance in the scattering axis direction TT: total light transmittance).

The “total light transmittance” in the present invention is a value measured according to JIS K7361-1, and specifically, the ratio of the total light transmitted through the sample to the incident light using a CIE D ₆₅ standard light source. Is the value represented as

<(B) (c) First and second video projectors>
A first image projector 11 used in the image display system 100 shown in FIG. 1 is an image projector that projects an image on a linearly polarized light selective screen 10 with polarized light 12 in a first polarization direction. In addition, the second video projector 21 used in the video display system 100 shown in FIG. 1 projects an image with the polarized light 22 in the second polarization direction perpendicular to the first polarization direction with respect to the linear polarization selective screen 10. This is a video projector.

  The first and second video projectors used here may be arbitrary video projectors capable of projecting an image with polarized light. Specifically, for example, a video projector using a liquid crystal element as a two-dimensional optical switch, That is, it may be a liquid crystal projector.

  As described above, the second video projector used in the video display system of the present invention is a video projector that projects polarized light in the second polarization direction perpendicular to the first polarization direction. That is, the polarization direction of the polarized light 12 projected from the first video projector 11 and the polarized light 22 projected from the second video projector 21 are orthogonal to each other.

  Therefore, as shown in FIG. 1, the polarization direction of the polarized light 12 projected from the first video projector 11 is the scattering axis direction of the linearly polarized light selective screen 10, thereby projecting from the first video projector 11. When the image to be displayed is displayed on the linear polarization selective screen 10, the polarization direction of the polarized light 22 projected from the second image projector 21 is the transmission axis direction of the linear polarization selective screen 10, thereby The image projected from the second image projector 20 is not displayed on the linearly polarized light selective screen.

  On the other hand, as shown in FIG. 2, the polarization direction of the polarized light 22 projected from the second video projector 21 is the scattering axis direction of the linearly polarized light selective screen 10, thereby the second video projector 21. Is displayed on the linearly polarized light selective screen 10, the polarization direction of the polarized light 12 projected from the first video projector 11 is the transmission axis direction of the linearly polarized light selective screen 10. Accordingly, the image projected from the first image projector 11 is not displayed on the linearly polarized light selective screen 10.

  That is, only one of the images projected from the first and second image projectors is displayed on the linear polarization selective screen.

<(D) Switching device>
The switching device used in the video display system 100 shown in FIG. 1 is one of the first and second polarization directions, that is, the polarization direction of polarized light projected from one of the first and second video projectors. Are switched to be in the direction of the scattering axis of the linearly polarized light selective screen.

  As described above with respect to the first and second video projectors, only one of the images projected from the first and second video projectors is displayed on the linear polarization selective screen. Therefore, according to this switching device, only one of the images projected from the first and second image projectors is switched and displayed on the linear polarization selective screen.

<(D) Switching device-Screen rotating device>
The switching device used in the image display system shown in FIG. 1 rotates the linearly polarized light selective screen so that the scattering axis of the linearly polarized light selective screen is parallel to one of the first and second polarization directions. It may be a screen rotation device that switches as described above.

  In one example, the screen rotation device is a device that rotates the linear polarization selective screen about the normal axis of the linear polarization selective screen 10.

  This screen rotating device will be described with reference to FIGS. That is, in this screen rotating device, the screen 10 is rotated about the normal axis 10a of the screen 10 as shown by the arrow 10c, so that the scattering axis 10b of the screen 10 has the first and second images. It rotates relative to the first and second polarization directions, which are the polarization directions of the polarized light projected from the projector. Therefore, according to this, the scattering axis 10b of the linearly polarized light selective screen 10 can be switched so as to be parallel to either the first or second polarization direction.

  In another example, the screen rotation device is a device that rotates the linearly polarized light selective screen around an axis in the plane direction of the linearly polarized light selective screen.

  This screen rotation device will be described with reference to FIGS. That is, in this screen rotating apparatus, the screen 10 is rotated around the axis 10a ′ in the surface direction of the screen 10 as indicated by the arrow 10c ′, so that the scattering axis 10b ′ of the screen 10 becomes the first and second axes. Rotate relative to the first and second polarization directions, which are the directions of polarization of the polarized light projected from the video projector. Therefore, according to this, the scattering axis 10b 'of the linearly polarized light selective screen 10 can be switched so as to be parallel to one of the first and second polarization directions.

  In addition, in the screen rotating apparatus as shown in FIGS. 3 and 4, for example, as shown in FIG. 4C, the screen can be divided and the divided individual screens can be rotated. In addition, these screen rotating devices can be specifically composed of a rotating shaft of the screen, a motor for rotating the screen around the rotating shaft, and the like.

<(D) Switching device-Polarization rotation device>
The switching device used in the video display system shown in FIG. 1 rotates the polarized light in the first and second polarization directions around the projection direction axis of the respective polarized light, and changes the first and second polarization directions. Either may be a polarization rotator that switches to be parallel to the scattering axis of the linear polarization selective screen.

  In one example, the polarization rotation device is configured to change the polarization of each of the first and second polarization directions by a retardation film, particularly a retardation film having a half-wave retardation in the central region of visible light. It is a device that rotates around the projection direction axis.

  Specifically, this polarization rotation device rotates a linearly polarized light by 90 ° by repeatedly inserting and removing a retardation film between the first and second image projectors and the linearly polarized light selective screen. And can be switched to be parallel to one of the first and second polarization directions.

  In another example, the polarization rotation device rotates the first and second image projectors themselves to rotate the polarized light in the first and second polarization directions around the projection direction axis of each polarization. Device.

FIG. 1 is a schematic diagram showing one state of the video display system of the present invention. FIG. 2 is a schematic view showing another state of the video display system of the present invention. FIG. 3 is a schematic diagram illustrating one embodiment of a screen rotation device that rotates a linearly polarized light selective screen. FIG. 4 is a schematic view showing another aspect of the screen rotation device for rotating the linearly polarized light selective screen.

DESCRIPTION OF SYMBOLS 10 1st screen 10a, 10a 'Rotating shaft 10b, 10b' Scattering shaft 10c, 10c 'Arrow which shows rotation direction 11 1st image projector 21 2nd image projector 100 Image display system A, B observer of this invention

Claims (7)

(A) a linearly polarized light selective screen having in-plane a scattering axis that maximizes scattering with respect to linearly polarized light and a transmission axis that minimizes scattering with respect to linearly polarized light;
(B) a first image projector that projects an image with polarized light in a first polarization direction on the linearly polarized light selective screen;
(C) a second image projector for projecting an image with a polarization in a second polarization direction perpendicular to the first polarization direction with respect to the linear polarization selective screen; and (d) the first and second A switching device for switching so that any one of the polarization directions of the linearly polarized light selective screen is a scattering axis direction of
A video display system.   The screen rotation device, wherein the switching device rotates the linearly polarized light selective screen and switches the scattering axis of the linearly polarized light selective screen to be parallel to one of the first and second polarization directions. The video display system according to claim 1, wherein   The video display system according to claim 2, wherein the screen rotation device rotates the linearly polarized light selective screen around an axis in a normal direction of the linearly polarized light selective screen.   The video display system according to claim 2, wherein the screen rotation device rotates the linearly polarized light selective screen around an axis in a plane direction of the linearly polarized light selective screen.   The switching device rotates the polarized light in the first and second polarization directions around a projection direction axis of each polarized light, and one of the first and second polarization directions is the linear polarization selection. The image display system according to claim 1, wherein the image display system is a polarization rotation device that switches so as to be parallel to the scattering axis of the active screen.   The video display system according to claim 5, wherein the polarization rotation device rotates the polarized light in the first and second polarization directions around a projection direction axis of each polarization by a retardation film.   6. The polarization rotation device rotates the first and second image projectors themselves to rotate the polarized light in the first and second polarization directions around the projection direction axis of each polarization. The video display system described in 1.

Images