JP2003185969A - Liquid crystal projector system with stereoscopic vision - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquid crystal projector system with stereoscopic vision which does not require a change of design in the optical element of an existing liquid crystal projector. <P>SOLUTION: In the liquid crystal projectors C and D, a liquid crystal light valve 32 for green emits P-polarized image light, and a liquid crystal light valve 31 for red and a liquid crystal light valve 33 for blue emit S-polarized image light. An image signal path converting part 22 supplies a red image signal Rl for the left eye, a blue image signal Bl for the left eye and a green image signal Gr for the right eye to the liquid crystal projector C, and supplies a red image signal Rr for the right eye, a blue image signal Br for the right eye, and a green image signal Gl for the left eye to the liquid crystal projector D. A phase plate 23 is mounted at the optical emission side of the projection lens 19 of the liquid crystal projector D. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a stereoscopic liquid crystal projector system.

[0002]

2. Description of the Related Art FIG. 4 is a diagram showing an optical system of a general three-plate type color liquid crystal projector. Light emitting unit 2 of light source 1
Is composed of an ultra-high pressure mercury lamp, a metal halide lamp, a xenon lamp, etc., and its irradiation light is emitted as parallel light by the parabolic reflector 3 and guided to the integrator lens 4.

The integrator lens 4 is composed of a pair of lens groups 4a and 4b, and each lens pair guides the light emitted from the light source 1 to the entire surface of a liquid crystal light valve described later. The light passing through the integrator lens 4 is guided to the first dichroic mirror 8 after passing through the polarization conversion device 5, the condenser lens 6, and the total reflection mirror 7.

The polarization conversion device 5 is composed of a polarization beam splitter array (hereinafter referred to as a PBS array). The PBS array consists of a polarization separation film and a retardation plate (1
/ 2λ plate). Each polarization separation film of the PBS array allows, for example, P-polarized light of the light from the integrator lens 3 to pass therethrough, and changes the S-polarized light path by 90 °. The S-polarized light having the optical path polarized is reflected by the adjacent polarization separation film and is emitted as it is. On the other hand, the P-polarized light transmitted through the polarization separation film is converted into S-polarized light by the retardation plate provided on the front side (light emission side) thereof and is emitted. That is, almost all light is converted into S-polarized light.

The first dichroic mirror 8 transmits light in the red wavelength band and reflects light in the cyan (green + blue) wavelength band. The light in the red wavelength band that has passed through the first dichroic mirror 8 is reflected by the total reflection mirror 9 and the optical path thereof is changed. The red light reflected by the total reflection mirror 9 is optically modulated by passing through the transmissive liquid crystal light valve 31 for red light. On the other hand, the light in the cyan wavelength band reflected by the first dichroic mirror 8 is guided to the second dichroic mirror 11.

The second dichroic mirror 11 transmits light in the blue wavelength band and reflects light in the green wavelength band. The light in the green wavelength band reflected by the second dichroic mirror 11 is guided to the transmissive liquid crystal light valve 32 for green light, and is transmitted through this to be optically modulated. Also,
The blue wavelength band light transmitted through the second dichroic mirror 11 includes the relay lens 13, the total reflection mirror 14, the relay lens 15, the total reflection mirror 16, and the relay lens 17.
After passing through, the light is guided to the transmission type liquid crystal light valve 33 for blue light, and the light is modulated by transmitting the light.

Each liquid crystal light valve 31, 32, 33 has a
An incident side polarization plate, and a panel section formed by enclosing a liquid crystal between a pair of glass substrates (on which a pixel electrode and an alignment film are formed),
And an emission side polarization plate.

The modulated light (image light of each color) modulated by passing through the liquid crystal light valves 31, 32, 33 is combined by the dichroic prism 18 to be combined image light (color image light). This synthetic image light is transmitted through the projection lens 19
The image is enlarged and projected by, and is projected and displayed on the screen 20.

Here, since the liquid crystal light valve 32 for generating the green image light is of a type in which the polarization direction of the emitted light is rotated by 90 ° with respect to the polarization direction of the incident light, the green image light is P-polarized and the red image light is red. Liquid crystal light valve 31 for generating image light and liquid crystal light valve 33 for generating blue image light
Is a type in which the polarization direction of emitted light matches the polarization direction of incident light, and red image light and blue image light are S-polarized light.

FIG. 5 shows a stereoscopic liquid crystal projector system constructed by using two liquid crystal projectors A and B. The liquid crystal projectors A and B have basically the same configuration as the liquid crystal projector shown in FIG. In order for the observer to recognize the stereoscopic image, it is necessary to emit the S-polarized image for the left eye from the first liquid crystal projector A and the P-polarized image for the right eye from the second liquid crystal projector B, for example. is there.
An observer can recognize a stereoscopic image by wearing stereoscopic glasses having an S-polarized transparent film on the left eye side and a P-polarized transparent film on the right eye side.
Therefore, in the stereoscopic liquid crystal projector system of FIG. 5, in the liquid crystal projectors A and B, for example, by arranging the phase difference plate 41 on the image light emitting side of the liquid crystal light valve 32 that generates green image light, a composite image is obtained. The entire light is S-polarized. Further, in the liquid crystal projector B, a retardation plate 42 that converts the entire combined image light into P-polarized light is further arranged.

[0011]

However, in each of the liquid crystal projectors A and B, the characteristics of the dichroic prism 18 are optimized under the condition that the red image light and the blue image light are S-polarized and the green image light is P-polarized. As described above, the dichroic prism 1
If the green image light before entering 8 is converted into S-polarized light, optimum color combination cannot be performed. On the other hand, if the dichroic prism 18 is newly designed, the cost will increase. In addition, it causes deterioration of optical characteristics.

In view of the above circumstances, it is an object of the present invention to provide a stereoscopic liquid crystal projector system which does not require a design change of optical elements of an existing liquid crystal projector.

[0013]

In order to solve the above-mentioned problems, a stereoscopic liquid crystal projector system according to the present invention is an image in which first polarized red image light and blue image light are combined with second polarized green image light. A first liquid crystal projector and a second liquid crystal projector having a light synthesizing means are provided, and the second liquid crystal projector is further provided with a polarization conversion element for rotating the polarization direction of the combined image light, and a red image and a blue image among the images for one eye. Are supplied to the first liquid crystal projector, green images are supplied to the second liquid crystal projector, and red and blue images of the other eye image are supplied to the second liquid crystal projector, and green images are supplied to the first liquid crystal projector. It is characterized in that a signal supply means is provided.

With the above arrangement, on the projected image, the red image light, the green image light and the blue image light which form one eye image are aligned with the first polarization, and the red image light which forms the other eye image. The green image light and the blue image light are aligned with the second polarized light, and the viewer has the first polarized light transmission film on one eye side and the second polarized light transmission film on the other eye side as stereoscopic eyeglasses. You can recognize a stereoscopic image by wearing an object. In each of the liquid crystal projectors that form the stereoscopic liquid crystal projector system, the existing image light combining means can be used as it is, and the cost can be reduced.

The polarization conversion element is preferably arranged on the light exit side of the projection lens. According to this, polarization conversion can be performed without modifying the inside of each liquid crystal projector.

In the stereoscopic liquid crystal projector system of the present invention, only the green image light is included in the image light combining means for combining the first polarized red image light and blue image light with the second polarized green image light, and the combined image light. A first liquid crystal projector and a second liquid crystal projector each having a wavelength selection polarization conversion element that rotates the polarization direction are provided, and the second liquid crystal projector is further provided with a polarization conversion element that rotates the polarization direction of the combined image light. An image signal supplying means for supplying an image to the first liquid crystal projector and an image for the other eye to the second liquid crystal projector is provided.

With the above arrangement, on the projected image, the red image light, the green image light and the blue image light which form one eye image are aligned with the first polarization, and the red image light which forms the other eye image. The green image light and the blue image light are aligned with the second polarized light, and the viewer has the first polarized light transmission film on one eye side and the second polarized light transmission film on the other eye side as stereoscopic eyeglasses. You can recognize a stereoscopic image by wearing an object. Each of the liquid crystal projectors forming the stereoscopic liquid crystal projector system may be provided with the wavelength selection polarization conversion element, and the image light combining means can be used as it is, and the cost can be reduced.

In the stereoscopic liquid crystal projector system having the above structure, the wavelength selective polarization conversion element may be provided on the light incident side of the projection lens in the liquid crystal projector. On the other hand, if the wavelength-selective polarization conversion element is provided on the light exit side of the projection lens in the liquid crystal projector, polarization conversion can be performed without modifying the inside of each liquid crystal projector. Further, in such a configuration, the wavelength selection polarization conversion element and the polarization conversion element of the second liquid crystal projector may be integrated.

Further, the stereoscopic liquid crystal projector system of the present invention includes a first liquid crystal projector and a second liquid crystal having image light combining means for combining the first polarized red image light and the blue polarized image light with the second polarized green image light. A projector is provided, a first liquid crystal projector is provided with a wavelength selection polarization conversion element that rotates the polarization direction of only green image light of the combined image light, and a second liquid crystal projector is provided with red image light and blue image light of the combined image light. Is provided with a wavelength selection polarization conversion element for rotating the polarization direction, and video signal supply means for supplying one eye image to the first liquid crystal projector and supplying the other eye image to the second liquid crystal projector. Characterize.

With the above-mentioned structure, on the projected image, the red image light, the green image light, and the blue image light which form one eye image are aligned with the first polarization, and the red image light which forms the other eye image. The green image light and the blue image light are aligned with the second polarized light, and the viewer has the first polarized light transmission film on one eye side and the second polarized light transmission film on the other eye side as stereoscopic eyeglasses. You can recognize a stereoscopic image by wearing an object. Each of the liquid crystal projectors constituting the stereoscopic liquid crystal projector system may be provided with wavelength selective polarization conversion elements having different wavelength selectivity, and the image light combining means can be used as it is, and the cost can be reduced.

In the stereoscopic liquid crystal projector system having the above structure, it is preferable that the wavelength selective polarization conversion element is provided on the light emitting side of the projection lens.

In the stereoscopic liquid crystal projector system according to any one of the above, the image composition means may be a dichroic prism.

Further, the stereoscopic liquid crystal projector system of the present invention uses a plurality of liquid crystal projectors and controls the supply of the red video signal, the green video signal and the blue video signal to each liquid crystal projector to display a projected video image. Then
The red image light, the green image light and the blue image light forming the image for one eye are aligned with the first polarization, and the red image light, the green image light and the blue image light forming the image for the other eye are aligned with the second polarization. It is characterized by being configured in.

Further, the stereoscopic liquid crystal projector system of the present invention uses a plurality of liquid crystal projectors, and each liquid crystal projector selectively converts the polarization direction of only a desired color video light of the composite video light. By including the conversion element, the red image light, the green image light, and the blue image light forming one eye image are aligned in the first polarization on the projected image, and the red image light and the green image forming the other eye image are aligned. It is characterized in that the light and the blue image light are aligned in the second polarized light.

[0025]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS (First Embodiment) A stereoscopic liquid crystal projector system according to a first embodiment of the present invention will be described below with reference to FIG. In this embodiment, the liquid crystal projectors shown in FIG. 4 of the related art are used as the liquid crystal projectors C and D constituting the stereoscopic liquid crystal projector system. That is, the liquid crystal light valve 32 for green emits P-polarized image light, and the liquid crystal light valve 31 for red and the liquid crystal light valve 33 for blue emit S light.
The polarized image light is emitted.

The video signal output unit 21 includes an L (left eye) video signal output unit 21a and an R (right eye) video signal output unit 21b.
With. The L video signal output unit 21a outputs a red video signal Rl, a green video signal Gl, a blue video signal Bl, and a synchronization signal l. The R video signal output unit 21a includes a red video signal Rr, a green video signal Gr, and a blue video signal B.
r and the synchronization signal r are output.

The video signal path conversion unit 22 supplies the red video signal Rl, the blue video signal Bl, and the synchronization signal 1 output from the L video signal output unit 21a to the liquid crystal projector C, and the green video signal Gl to the liquid crystal. Supply to the projector D. Then, the red video signal Rr and the blue video signal Br output from the R video signal output unit 21b are supplied to the liquid crystal projector D, and the green video signal Gr is supplied to the liquid crystal projector C.
Supply to. The sync signal r output from the R video signal output unit 21b is processed so as to match the sync signal l output from the L video signal output unit 21a, and then supplied to the liquid crystal projector D for R Video signal output unit 21b
The video signal output from is output based on the synchronization signal subjected to the matching process.

Only in the liquid crystal projector D, the phase difference plate 23 is attached to the light emitting side of the projection lens 19. Therefore, from the liquid crystal projector C, the S-polarized red image for the left eye, the S-polarized blue image for the left eye, and the P image are displayed.
The polarized green image for the right eye is projected, and the liquid crystal projector D
From, a P-polarized right-eye red image, a P-polarized right-eye blue image, and an S-polarized left-eye green image are projected. Therefore, in the projected image on the screen 20, the red image light, the green image light, and the blue image light that form the left-eye image are all S-polarized, and the red image light and the green image light that form the right-eye image. All blue image light will be P-polarized,
An observer can recognize a stereoscopic image by wearing stereoscopic eyeglasses having an S-polarized transparent film on the left eye side and a P-polarized transparent film on the right eye side. Each liquid crystal projector C constituting the stereoscopic liquid crystal projector system
In D, the existing dichroic prism 18 can be used as it is, and the cost can be reduced. Further, since the phase difference plate 23 is provided on the light emitting side of the projection lens 19, it is possible to perform polarization conversion without modifying the inside of the liquid crystal projector D.

(Second Embodiment) A stereoscopic liquid crystal projector system according to a second embodiment of the present invention will be described below with reference to FIG. In this embodiment, each of the liquid crystal projectors E and F constituting the stereoscopic liquid crystal projector system adopts the basic configuration of the liquid crystal projector shown in FIG. The dichroic prism 18 is provided on the light emitting side. The green light selective polarization conversion element 24
For wavelength selective polarization conversion elements (color switches) such as SID (SOCIETY FOR INFORMATION DISPLAY INTERNATI
ONAL SYMPOSIOM DIGEST OF TECHNICAL PAPERS) VOLUME X
XXI P.96-P.99 (9.4: High Throughput Color Switch For
Sequential Color Projection) and is publicly known.

The video signal output unit 21 includes an L video signal output unit 21a and an R video signal output unit 21b. The L video signal output unit 21 a supplies the red video signal Rl, the green video signal Gl, the blue video signal Bl, and the synchronization signal 1 to the liquid crystal projector E. The R video signal output unit 21a includes
Red video signal Rr, green video signal Gr, blue video signal B
The r and the synchronization signal r are supplied to the liquid crystal projector F.

From the dichroic prism 18 of the liquid crystal projector E, the S-polarized red image for the left eye, the S-polarized blue image for the left eye, and the P-polarized green image for the left eye are emitted. Since the image light passes through the green light selective polarization conversion element 24, only the left-eye green image is converted into S-polarized light. Therefore, the liquid crystal projector E projects an image for the left eye of each color, which is aligned in S polarization. Similarly, in the liquid crystal projector F, the image for the right eye of each color aligned to S-polarized light is emitted through the green light selective polarization conversion element 24, but the phase difference plate 23 provided on the light emission side of the projection lens 19 is used. Thus, the polarization directions of all color image lights are converted by 90 ° and projected as P-polarized light. Therefore, screen 2
In the projection image on 0, the red image light, the green image light, and the blue image light forming the image for the left eye are all S-polarized,
The red image light, the green image light, and the blue image light forming the image for the right eye are all aligned with P-polarized light, and the observer has a P-polarized transmission film on the right eye side as stereoscopic eyeglasses and has a left-eye side. A stereoscopic image can be recognized by wearing an S-polarized transparent film. The existing dichroic prism 18 can be used as it is in each of the liquid crystal projectors E and F constituting the stereoscopic liquid crystal projector system, and the cost can be reduced.

Incidentally, the green light selective polarization conversion element 24 may be detachably provided on the light emitting side of the projection lens 19, and according to this, the inside of the liquid crystal projectors E and F can be kept unchanged. The polarization conversion of green image light can be performed, and when used as an ordinary liquid crystal projector, the green light selective polarization conversion element 24 may be removed and used. Further, in the liquid crystal projector F, there is an advantage that the number of additional parts can be reduced by integrating the retardation plate 23 and the green light selective polarization conversion element 24.

(Third Embodiment) A stereoscopic liquid crystal projector system according to a third embodiment of the present invention will be described below with reference to FIG. In addition, in this embodiment, the liquid crystal projectors G and H constituting the stereoscopic liquid crystal projector system are both the liquid crystal projectors shown in FIG.

The video signal output unit 21 includes an L video signal output unit 21a and an R video signal output unit 21b. The L video signal output unit 21a supplies the red video signal Rl, the green video signal Gl, the blue video signal Bl, and the synchronization signal 1 to the liquid crystal projector G. The R video signal output unit 21a includes
Red video signal Rr, green video signal Gr, blue video signal B
The r and the synchronization signal r are supplied to the liquid crystal projector H.

On the light exit side of the projection lens 19 of the liquid crystal projector G, there is provided a wavelength selection polarization conversion element 25 for converting the polarization direction of the green image light of the combined image light emitted from the dichroic prism 18 by 90 °. On the light emission side of the projection lens 19 of the liquid crystal projector H, a wavelength selection polarization conversion element 26 that converts the polarization directions of the red image light and the blue image light of the combined image light emitted from the dichroic prism 18 by 90 ° is provided. ing.

From the dichroic prism 18 of the liquid crystal projector G, an S-polarized left-eye red image, an S-polarized left-eye blue image, and a P-polarized left-eye green image are emitted. By passing the image light through the wavelength-selective polarization conversion element 25, only the left-eye green image is converted into S-polarized light. Therefore, the liquid crystal projector G projects the image for the left eye of each color, which is aligned in S polarization. Similarly, from the dichroic prism 18 of the liquid crystal projector H, S
A polarized red-eye image for the right eye, an S-polarized blue image for the right eye, and a P-polarized right-eye green image are emitted. By passing the image light through the wavelength selection polarization conversion element 26, The red image for the right eye and the blue image for the right eye are converted into P-polarized light. Therefore, the liquid crystal projector H projects an image for the right eye of each color, which is aligned with P-polarized light. Therefore, screen 2
In the projected image on 0, the red image light, the green image light, and the blue image light that form the image for the right eye are all P-polarized,
The red image light, the green image light, and the blue image light that form the image for the left eye are all S-polarized, and the observer has a P-polarized transmission film on the right eye side as stereoscopic eyeglasses and is provided on the left eye side. A stereoscopic image can be recognized by wearing an S-polarized transparent film. The existing liquid crystal projectors G and H constituting the stereoscopic liquid crystal projector system can be used as they are, and the cost can be reduced.

Further, in the above configuration, since the wavelength selective polarization conversion elements 25 and 26 are provided on the light emitting side of the projection lens 19, the inside of the liquid crystal projector can be maintained without any modification.
Polarization conversion of image light of any color can be performed, and when used as a normal liquid crystal projector, the wavelength selection polarization conversion elements 25 and 26 may be removed. Although such an effect cannot be obtained, the light wavelength selective polarization conversion element 2
5, 5 may be provided on the light incident side of the projection lens 19.

Further, in the above-described embodiments, the structure using the transmissive liquid crystal display panel is shown, but it can be applied to the case of using the reflective liquid crystal display panel.
Further, although the configuration using the dichroic prism as the image synthesizing means is shown, the invention is not limited to this, and a configuration using a dichroic mirror or the like may be used. That is, it is possible to use various existing configurations as the optical system of the liquid crystal projector, and to supply the red video signal, the green video signal, and the blue video signal to each liquid crystal projector by using such a plurality of liquid crystal projectors. By controlling, on the projected image, the red image light, the green image light and the blue image light which form one eye image are aligned with the first polarization, and the red image light and the green image light which form the other eye image are aligned. It suffices that the blue image light is aligned with the second polarized light. In addition, by using a plurality of liquid crystal projectors and providing each liquid crystal projector with a wavelength selection polarization conversion element that selectively converts the polarization direction of only the video light of any color of the composite video light, So that the red image light, the green image light, and the blue image light that form the eye image are aligned with the first polarization, and the red image light, the green image light, and the blue image light that form the other eye image are aligned with the second polarization. It may be configured.

[0039]

As described above, according to the present invention, in each liquid crystal projector constituting the stereoscopic liquid crystal projector system, the design change of the image light synthesizing means or the like is not required, so that the cost can be reduced and the optical characteristics can be improved. This has the effect of avoiding a decrease.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram showing a stereoscopic liquid crystal projector system according to a first embodiment of the present invention.

FIG. 2 is a schematic configuration diagram showing a stereoscopic liquid crystal projector system according to a second embodiment of the present invention.

FIG. 3 is a schematic configuration diagram showing a stereoscopic liquid crystal projector system according to a third embodiment of the present invention.

FIG. 4 is a configuration diagram showing an optical system of a general liquid crystal projector.

FIG. 5 is a schematic configuration diagram showing a conventional stereoscopic liquid crystal projector system.

[Explanation of symbols]

18 Dichroic prism 19 Projection lens 21 Video signal output section 22 Video signal path converter 23 Phase plate 24 Green selective polarization conversion element 25 wavelength selective polarization conversion element 26 Wavelength selective polarization conversion element 31 LCD display panel 32 LCD display panel 33 Liquid crystal display panel C LCD projector D LCD projector E LCD projector F LCD projector G LCD projector H LCD projector

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) G03B 35/20 G03B 35/20 (72) Inventor Hiroshi Yoshida 2-5-5 Keihanhondori, Moriguchi-shi, Osaka Sanyo Denki Co., Ltd. (72) Inventor Takehiko Asano 2-5-5 Keihan Hondori, Moriguchi City, Osaka Prefecture Sanyo Denki Co., Ltd. (72) Inventor Tetsuya Enoki 2-5 Keihan Hondori, Moriguchi City, Osaka Prefecture No. 5 Sanyo Electric Co., Ltd. F term (reference) 2H059 AA24 AA26 2H088 EA05 EA14 HA13 HA15 HA24 HA28 MA05 MA16 2H091 FA05Z FA11X FA26X FA41Z FD24 MA07

Claims (11)

[Claims] 1. A first liquid crystal projector and a second liquid crystal projector having image light combining means for combining first polarized red image light and blue image light with second polarized green image light, wherein the second liquid crystal projector is provided. Further, a polarization conversion element that rotates the polarization direction of the combined image light is provided, and among the images for one eye, the red image and the blue image are supplied to the first liquid crystal projector, the green image is supplied to the second liquid crystal projector, and the other eye is supplied. A stereoscopic liquid crystal projector system comprising a video signal supply means for supplying a red video image and a blue video image to the second liquid crystal projector and a green video image to the first liquid crystal projector. 2. The stereoscopic liquid crystal projector system according to claim 1, wherein the polarization conversion element is provided on a light emitting side of a projection lens. 3. An image light combining means for combining the first polarized red image light and blue image light with the second polarized green image light, and a wavelength selective polarization conversion element for rotating the polarization direction of only the green image light of the combined image light. A first liquid crystal projector and a second liquid crystal projector having, a second liquid crystal projector further provided with a polarization conversion element for rotating the polarization direction of the combined image light, and supplies one eye image to the first liquid crystal projector, A stereoscopic liquid crystal projector system comprising video signal supply means for supplying the other eye video to the second liquid crystal projector. 4. The stereoscopic liquid crystal projector system according to claim 3, wherein the wavelength selective polarization conversion element is provided on a light incident side of a projection lens in the liquid crystal projector. 5. The stereoscopic liquid crystal projector system according to claim 3, wherein the wavelength selective polarization conversion element is provided on a light emitting side of a projection lens in the liquid crystal projector. 6. The stereoscopic liquid crystal projector system according to claim 5, wherein the wavelength selection polarization conversion element and the polarization conversion element of the second liquid crystal projector are integrated. 7. A first liquid crystal projector and a second liquid crystal projector having image light synthesizing means for synthesizing first polarized red image light and blue image light and second polarized green image light, wherein the first liquid crystal projector is provided. A wavelength selection polarization conversion element that rotates the polarization direction of only the green image light of the combined image light is provided, and the second liquid crystal projector rotates the polarization direction of the red image light and the blue image light of the combined image light. A stereoscopic liquid crystal projector system comprising an element, and video signal supply means for supplying one eye image to the first liquid crystal projector and supplying the other eye image to the second liquid crystal projector. 8. The stereoscopic liquid crystal projector system according to claim 7, wherein the wavelength selective polarization conversion element is provided on a light emitting side of a projection lens. 9. The stereoscopic liquid crystal projector system according to claim 1, wherein the image synthesizing means is a dichroic prism. 10. A red image forming one eye image on a projected image by controlling the supply of a red image signal, a green image signal and a blue image signal to each liquid crystal projector using a plurality of liquid crystal projectors. It is characterized in that the image light, the green image light and the blue image light are aligned with the first polarization, and the red image light, the green image light and the blue image light forming the other eye image are aligned with the second polarization. 3D LCD projector system. 11. A plurality of liquid crystal projectors are used, and each liquid crystal projector is provided with a wavelength-selective polarization conversion element that selectively converts the polarization direction of only an image light of an arbitrary color of the combined image light. Then, the red image light, the green image light, and the blue image light that form the image for one eye are aligned with the first polarization, and the red image light, the green image light, and the blue image light that form the image for the other eye are the second polarization. A stereoscopic liquid crystal projector system, which is configured to be aligned.