JPH112814A - Optical system of lcd projector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To remove the generation of a screen color difference by correcting transimissivity accompanying a difference in angle of incidence through a gradient coating process. SOLUTION: A dichroic prism 234 reflects a red (R) image and a blue (B) image on the basis of an S wave and transmits a green (G) image on the basis of a P wave. Further, a dichroic mirror 208 and 1st and 3rd reflecting mirrors 216 and 220 on the optical paths of R, G, and B are processed by gradient coating to reduce color differences of the images by correcting variation in transmissivity due to the difference in angle of incidence of incident light on coating surfaces A and B of the dichroic prism 234. The R and B of the S wave and the G of the P wave form images on R, G, and B LCD panels 228, 230, and 232 and the formed images are chromatically synthesized by the dichroic prism 234 and then outputted thereafter on a screen through a projection lens 236, so that an enlarged image is formed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention
The present invention relates to a three-panel (Panel) LCD projector which is separated into G (green) and B (blue) and is suitable for synthesizing. In particular, the present invention relates to a method in which G of P wave is projected through a dichroic prism. The present invention relates to an optical system of a panel LCD projector.

[0002]

2. Description of the Related Art In general, an LCD projector is connected to a television receiver or a video so as to project an image on an external screen, and is mainly used for presentation in a conference room and in a small theater. Projectors are used as replacements for large CRTs in homes.

[0003] The optical system of the LCD projector thus configured has a lamp 10 as shown in FIG.
The ultraviolet light and heat light shielding mirror 102 coated so as to block the ultraviolet light and heat light component of the incident light diverged from 0, and the ultraviolet light and heat light shield mirror 102 block the ultraviolet light and heat light. First and second integrator lenses 104 for uniformly irradiating the beam as a whole,
106, the first and second integrator lenses 104,
From the incident light evenly focused by
R reflection dichroic mirror 108 that reflects (red)
A G-reflecting dichroic mirror 110 for selectively transmitting B (blue) from incident light transmitted through the R-reflecting dichroic mirror 108, and a long optical path of B transmitted through the G-reflecting dichroic mirror 110. The first and second relay lenses 112 and 114, the first reflection mirror 116 that reflects R reflected by the R reflection dichroic mirror 108, and changing the optical path of B transmitted through the G reflection dichroic mirror 110 by 180 degrees. Second and third reflection mirrors 118 and 120 disposed opposite to each other so as to make the G reflection dichroic mirror 1
The first, second and third condenser lenses 122, 124 and 126 for converging the respective R, G and B incident by the 10 and first and third reflection mirrors 116 and 120, and the first, second and third condenser lenses R focused through lenses 122, 124, 126,
A polarizer 128 is disposed in front of and behind liquid crystals 128a, 130a, and 132a so that G and B can form respective images.
b, 130b, 132b and analyzers 128c, 130c,
R, G, and BLCD panels 128, 130, and 132, which are combined with each other, and a dichroic prism 134 that combines the images formed by the R, G, and BLCD panels 128, 130, and 132 into one image. And a projection lens 136 for enlarging an image synthesized as one image by the dichroic prism 134 and projecting the screen S.

In the optical system of the conventional LCD projector configured as described above, the light emitted from the lamp 100, irradiated and reflected forward passes through the ultraviolet and heat light shielding mirror 102, After the light is blocked, the first and second integrator lenses 10
4 and 106 are evenly focused.

As described above, the white light focused forward through the first and second integrator lenses 104 and 106 contains R, G, B components, etc., where R is the R reflection dichroic mirror 108. After being reflected downward at, the light is reflected by the first reflecting mirror 116 and irradiates the first condenser lens 122. At this time, R, in which the P wave and the S wave coexist, is polarized by the polarizer 128b, the S wave is absorbed, and the P wave passes, so that the P wave is transmitted to the liquid crystal 128a and the analyzer. While passing through 128c, it is further converted into an S-wave whose polarization plane has changed by 90 degrees and is incident on the dichroic prism 134.

Further, the G is transmitted through the R reflection dichroic mirror 108 and then reflected further downward by 90 degrees at the G reflection dichroic mirror 110, so that the second
The light passes through the condenser lens 124. At this time, the G in which the P wave and the S wave coexist is incident on the polarizer 130b, the S wave is absorbed, the P wave passes through the liquid crystal 130a and the analyzer 130c, and is further converted into an S wave to be converted into a dichroic prism 134. Is incident on.

[0007] Further, B is the R reflection dichroic mirror 108 and G reflection dichroic mirror 110.
Are transmitted as a series, the second and third reflection mirrors 11
The third condenser lens 126 which is double-reflected at 8, 120
Pass through. At this time, the B wave where the P wave and the S wave coexist
Is polarized in the polarizer 132b, the S wave is absorbed, and the P wave is transmitted. This further passes through a liquid crystal 132a and an analyzer 132c, is converted into an S wave, and is incident on a dichroic prism 134.

[0008]

As described above, the R, G, and B of the S wave incident on the dichroic prism 134 are on the R, G, and B LCD panels 128, 130, and 132, as described above. An image is formed, and the image thus formed is combined with the dichroic prism 134.
Color synthesis, and thereafter, the image is output to the screen S through the projection lens 136 to form an enlarged image. At this time, the operation of the color composition is performed as follows.

The dichroic prism 134 has A and B surfaces, both surfaces of which are subjected to dichroic coating so that the A surface reflects only R and the B surface reflects only B. As a result, the RLCD panel 1
R that has passed through 28 transmits through the B surface, is reflected by the A surface, is incident on the projection lens 136, and enters the BLCD panel 13.
B that has passed through the surface 2 is transmitted through the surface A, is reflected on the surface B, and is incident on the projection lens 136.
G passes through all the surfaces A and B and is incident on the projection lens 136, whereby all the color components of R, G, and B are combined with the dichroic prism 134, and the light combined in this manner. Is incident on the projection lens 136,
An image is formed on the screen S.

On the other hand, G is transmitted through the second condenser lens and the GLCD panel as shown in FIG.
Dichroic but enters the click prism, right at this time, the G of B ₁ light the dichroic incident angle theta ₁ is B ₂ light less becomes the screen image from the incident angle theta ₂ of for A coated surface of the click prism for reflecting R A color difference occurs.

That is, if the incident angle increases, FIG.
As shown in (A) and (B), the characteristic curve shifts toward shorter wavelengths in the transmittance graph with respect to wavelength, and on the other hand, as the incident angle decreases, the characteristic curve increases with the wavelength. The curve shifts towards longer wavelengths. Therefore, the screen of the person who B ₁ light is incident is formed green image tinged red color, the image of the person who B ₂ light is incident green image tinged blue color is formed.

Therefore, in the three-panel LCD projector constructed and operated as described above, G passing through the dichroic prism is changed to S-wave in the GLCD panel and is incident on the dichroic prism, so that transmission efficiency is improved. Not only is the image darkened and the image becomes darker, but also there is a problem that a difference in the incident angle of the incident light occurs on the reflective coating surface inside the dichroic prism, and a difference in the amount of light appears on the left and right sides of the screen, causing a color difference on the screen. Was.

An object of the present invention is to solve the above-mentioned conventional problems, and in particular, to prevent a color difference on a screen caused by a light quantity difference between right and left sides of a screen and improve the brightness of the screen. It is an object of the present invention to provide an optical system for an LCD projector that can be operated.

[0014]

In order to achieve the above-mentioned object, an optical system of an LCD projector according to the present invention, in an LCD projector, blocks ultraviolet and heat light components of incident light radiated from a lamp in an LCD projector. And a first and second integrators for uniformly irradiating the UV and heat light shielding mirrors coated so that the UV and heat light shielding mirrors can block the UV light and heat light. An iter lens, an R-reflecting dichroic mirror that selectively reflects R from incident light that has been coated with the P-wave as a reference and is uniformly focused by the first and second integrator lenses, and a gradient.
And the S-wave is subjected to a coating process based on the S-wave, and the G-wave of the S-wave is obtained from the incident light transmitted through the R reflection dichroic mirror.
G reflecting dichroic mirror for selectively reflecting (green) light and B passing through the G reflecting dichroic mirror
First and second relay lenses for compensating for a long (blue) light path, and a gradient coating process,
A first reflecting mirror that reflects R (red) reflected from the reflecting dichroic mirror to the right, and a light path of B that has been subjected to a gradient coating process and has passed through the G reflecting dichroic mirror can be changed by 180 degrees. Second and third reflecting mirrors arranged so as to face each other, and first, second and third condensing light for converging each of R, G and B incident on the G reflecting dichroic mirror and the first and third reflecting mirrors. A coating process is performed on the front of the liquid crystal based on the S wave so that the lens and the R, G, and B focused through the first, second, and third condenser lenses can form respective images. The polarizers 228b and 232b coated on the basis of the polarizer and the P-wave are provided on the rear side, and the analyzer and P-wave coated on the basis of the S-wave are provided on the rear side. R, G, BLCD panels in which the coated analyzers are combined with each other, a dichroic prism for synthesizing each image formed by the R, G, BLCD panels into one image, and the dichroic It is characterized by including a projection lens for enlarging an image synthesized into one image by a prism and projecting the image on a screen.

Further, the ultraviolet and heat light shielding mirror has 20
99% or more is reflected at a wavelength of 0 to 400 nm,
It is characterized by being coated so that transmission and reflection are 50% at a wavelength of 420 nm and 97% or more are transmitted at a wavelength of 430 to 660 nm.

The R reflection dichroic mirror has four
At a wavelength of 400 to 570 nm, 97% or more of the incident light that is incident at 5 degrees is transmitted, 50% of the light is reflected and transmitted at a wavelength of 580 nm, and 99.9% or more of the light is reflected at a wavelength of 590 to 720 nm. It is characterized by being coated.

The G reflection dichroic mirror has four
At least 5% of the incident light incident at 5 degrees is transmitted at a wavelength of 400 to 490 nm, at least 97% is transmitted and reflected at a wavelength of 515 nm, and at least 99% is reflected at a wavelength of 520 to 650 nm. It is characterized by being coated.

Further, the polarizer 228b has an incident light of 580
0.1% or less is transmitted at a wavelength of 59 nm or less, and
At a wavelength of 0 nm, 50% is transmitted, 600-70
It is characterized in that it is coated so as to transmit at least 94% at a wavelength of 0 nm.

In the polarizer coated with the S wave as a reference, 0.1% or less of the incident light is transmitted at a wavelength of 495 nm or less, 50% of the incident light is transmitted at a wavelength of 515 nm, and 525 to 555 nm. More than 94% are transmitted at a wavelength of 50 nm and 50% at a wavelength of 560 nm.
% At the wavelength of 575-680 nm.
It is characterized by being coated so that 1% or less is transmitted.

Further, the polarizer 232b has an incident light of 380
0.1% transmitted at wavelengths below nm, 390n
50% transmitted at a wavelength of m, 400-500n
The coating treatment is performed so that 97% or more is transmitted at a wavelength of m, 50% is transmitted at a wavelength of 510 nm, and 0.1% or less is transmitted at a wavelength of 530 to 670 nm. .

The surface A of the dichroic prism is
A coating process is performed so that incident light incident at 45 degrees is transmitted at 0.1% or less at a wavelength of 570 nm or less, transmitted at 50% at a wavelength of 585 nm, and transmitted at 85% or more at a wavelength of 600 to 700 nm. It is characterized by having been done.

The surface B of the dichroic prism is
Coating treatment was performed so that incident light incident at 45 degrees was reflected at 85% or more at a wavelength of 400 to 500 nm, reflected at 50% at a wavelength of 520 nm, and transmitted at 1% or less at a wavelength of 530 nm or more. It is characterized by the following.

Further, the dichroic prisms A and B
The surface is coated so that 85% or more of horizontally incident light is transmitted at a wavelength of 480 to 620 nm.

[0024]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The optical system of an LCD projector according to the present invention has a G reflection dichroic mirror coated on the basis of an S wave, and the polarizer of the GLCD panel and the analyzer of the R and BLCD panels have polarization directions of S. The first and second polarizers of the R and B LCD panels and the analyzer of the GLCD panel are coated with the polarization direction of the P wave as a reference so that the left and right color differences on the screen can be corrected. , Three reflection mirrors and G
The reflection dichroic mirror is characterized in that a gradient coating is performed so that the thickness of the coating surface is different.

Hereinafter, embodiments according to the technical idea of the three-panel LCD projector of the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 is a block diagram showing a light path of an LCD projector to which the present invention is applied. As shown in the figure, an ultraviolet and heat light shielding mirror 202 coated so as to block ultraviolet and heat light components of incident light emitted from the lamp 200, and the ultraviolet and heat light shield mirror 2
02, a first and second integrator lens 20 for uniformly irradiating a beam from which ultraviolet light and heat light are blocked
4, 206; an R-reflecting dichroic mirror 208 that selectively reflects R from incident light that is coated on the basis of the P-wave and is uniformly focused by the first and second integrator lenses 204, 206; A G reflection dichroic mirror 210 for selectively reflecting G of the S wave from the incident light transmitted through the R reflection dichroic mirror 208 after being coated on the basis of the wave, and a long optical path of B transmitted through the G reflection dichroic mirror 210 And the first and second relay lenses 212 and 214 for compensating for the above, and the first reflecting mirror 216 for reflecting the R reflected by the R reflecting dichroic mirror 208 subjected to the gradient coating to the right.
The optical path of B, which has been subjected to the gradient coating process and transmitted through the G reflection dichroic mirror 210, is changed to 18
The second and third reflection mirrors 218 and 220 which are arranged to face each other so as to be able to be changed by 0 degrees, the G reflection dichroic mirror 210 and the first and third reflection mirrors 216,
The first, second, and third condenser lenses 222, 224, and 226 converge the respective R, G, and B incident by 220, and the first, second, and third condenser lenses 222, 224, and 226 converge. In front of the liquid crystals 228a, 230a, and 232a, a polarizer 230b coated on the basis of the S wave and a polarized light coated on the basis of the P wave so that R, G, and B can form respective images. The analyzers 228b and 232b are provided with analyzers 228c and 232c coated on the basis of the S wave and the analyzer 23 coated on the basis of the P wave.
R, G, BLCD panel 2 where 0c is mutually combined
28, 230, 232 and the dichroic prism 23 for combining the respective images formed by the R, G, BLCD panels 228, 230, 232 into one image.
4 and a projection lens 236 for enlarging an image synthesized as one image by the dichroic prism 234 and projecting it on the screen S. This will be described in more detail below. .

The ultraviolet and heat light shielding mirror 202 is
Coating is performed so that 99% or more is reflected at a wavelength of 200 to 400 nm, transmission and reflection is 50% at a wavelength of 420 nm, and 97% or more is transmitted at a wavelength of 430 to 660 nm.

The R reflection dichroic mirror 2
08 indicates that the incident light incident at 45 degrees is 400 to 570n.
at a wavelength of 580 nm, each is reflected and transmitted at a wavelength of 580 nm, and 590 to 72, respectively.
Coating is performed so that 99.9% or more is reflected at a wavelength of 0 nm.

The G reflection dichroic mirror 2
10, the incident light incident at 45 degrees is 400 to 490 n
at a wavelength of m, more than 97% is transmitted, and at a wavelength of 515 nm, 50% is transmitted and reflected respectively, and 520 to 650
The coating treatment is performed so that 99% or more is reflected at a wavelength of nm.

Further, the polarizer 228b has an incident light of 5
0.1% or less is transmitted at a wavelength of 80 nm or less,
At a wavelength of 590 nm, 50% is transmitted;
The coating treatment is performed so that 94% or more is transmitted at a wavelength of 700 nm.

In addition, the polarizer 230b controls the incident light to 4
0.1% or less is transmitted at a wavelength of 95 nm or less,
At a wavelength of 515 nm, 50% is transmitted;
At a wavelength of 555 nm, more than 94% is transmitted and 56
At a wavelength of 0 nm, 50% is transmitted, 575-68
Coating is performed so that 0.1% or less is transmitted at a wavelength of 0 nm.

Further, the polarizer 232b controls the incident light to 3
At wavelengths below 80 nm, 0.1% is transmitted and 39
At a wavelength of 0 nm, 50% is transmitted, 400 to 50
At a wavelength of 0 nm, 97% or more is transmitted, and 510n
50% transmitted at m wavelengths, 530-670n
The coating is performed so that 0.1% or less is transmitted at a wavelength of m.

The dichroic prism 234
In the A-plane, 0.1% or less of the incident light incident at 45 degrees is transmitted at a wavelength of 570 nm or less, 50% is transmitted at a wavelength of 585 nm, and 85% or more is transmitted at a wavelength of 600 to 700 nm. Coated.

The dichroic prism 234
B surface has an incident light incident at 45 degrees from 400 to 500
85% or more is reflected at a wavelength of nm, and 520 nm
The coating treatment is performed so that 50% is reflected at a wavelength of 530 nm and 1% or less is transmitted at a wavelength of 530 nm or more.

At this time, the dichroic prism 23
In the A and B planes of No. 4, the incident light that is horizontally incident is 480 to 480.
The coating treatment is performed so that 85% or more is transmitted at a wavelength of 620 nm.

The three-panel LCD projector configured as described above first emits light from the lamp 200,
The light irradiated and reflected forward has a wavelength of 400 nm
A first and second integrator 204 that converges uniformly in a state where both heat light and ultraviolet light are shielded through the ultraviolet light and heat light shielding mirror 202 having a characteristic of reflecting 99.9% or more at a wavelength of 0 nmλ or more; 206
And passes through the R reflection dichroic mirror 208 as a series.

As described above, the first and second integrators 2
R, G, B to white light focused through
Components, etc., but the above R (about 640 to 780 n
mλ) is 9 at a wavelength of 590 to 720 nm of the incident light.
After being reflected by the R reflection dichroic mirror 208 having a characteristic of reflecting 9.9% or more, the light is reflected by the first reflection mirror 216 at 90 degrees, and is reflected by the first condenser lens 22.
After that, the light is incident on the RLCD panel 228. At this time,
R, which is a state in which the P wave and the S wave coexist, indicates that the P wave is absorbed by the polarizer 228b coated on the basis of the P wave, and the P wave is passed. While passing through 228c, it is converted into an S-wave whose polarization plane has changed by 90 degrees, and is incident on the dichroic prism 234.

The above G (about 490 to 550 nmλ)
Is a G reflection dichroic which has a property of transmitting at least 50% at a wavelength of 515 nm of the incident light after transmitting through the R reflection dichroic mirror 208 having a property of transmitting 97% or more at a wavelength of 400 to 570 nm of the incident light. The light is reflected downward by 90 degrees from the mirror 210 and passes through the second condenser lens 224. At this time, the G in which the P wave and the S wave coexist is incident on the G reflection dichroic mirror 210 and the polarizer 230b coated on the basis of the S wave, the P wave is absorbed, and the S wave continues. The light passes through the liquid crystal 230a and the analyzer 230c and is converted into a P-wave and is incident on the dichroic prism 234.

The B (430 to 490 nmλ) is at least 98% at the wavelength of 400 to 490 nm of the incident light and the R reflection dichroic mirror 208 having the characteristic of transmitting 97% or more at the wavelength of 400 to 570 nm of the incident light. After passing through the G reflection dichroic mirror 210 having the property of transmitting light, the first and second relay lenses 212 and 214 maintain the light quantity, and are double-reflected by the second and third reflection mirrors 218 and 220 and thirdly condensed. Lens 2
26 is irradiated.

At this time, B in which the P wave and the S wave coexist is
Polarized in a polarizer 232b coated with respect to the P-wave, the S-wave is absorbed and the P-wave is transmitted. This passes through the liquid crystal 232a and the analyzer 232c again, is converted into an S wave, and is incident on the dichroic prism 234. At this time, R, G, and B incident on the dichroic prism 234 are polarizers 2 having a characteristic of transmitting 94% or more at a wavelength of 600 to 700 nm of incident light.
A polarizer 230b having a characteristic of transmitting 94% or more at a wavelength of 525 to 555 nm of incident light;
The incident light passes through the polarizer 232b having a characteristic of transmitting 97% or more at a wavelength of 400 to 500 nm.

The R reflection dichroic mirror 208 and the first and third reflection mirrors 21 on the R, G, and B light paths are used.
By performing a gradient coating process on the surfaces 8 and 222, a change in transmittance due to a difference in incident angle of incident light on the A and B coating surfaces of the dichroic prism 234 can be corrected to reduce a color difference of an image. .

As described above, R and B of the S wave and G of the P wave
Are the R, G, BLCD panels 228, 230, 23
An image is formed on the screen 2, and the thus formed image is subjected to color synthesis by the dichroic prism 234 and thereafter output to the screen S through the projection lens 236 to form an enlarged image. is there. The color synthesis operation at this time is performed as follows.

The dichroic prism 234 includes
The coating surfaces indicated by A and B are formed to be different from each other.
% Is reflected, and only R is reflected on the A-coated surface having a characteristic of reflecting only 0.1% at 570 nmλ or less, and 85% at 400 to 500 nmλ.
In the B-coated surface having the characteristic of reflecting the above and reflecting only 1% or less at 530 nmλ or more,
The dichroic coating process is performed so that only the light is reflected.

G is transmitted through the combined A and B coated surfaces so as to have a characteristic of transmitting at least 85% at 480 to 620 nm λ. As a result, the RLCD panel 228
Is transmitted through the B-coated surface, is reflected on the A-coated surface, is incident on the projection lens 236, and B that has passed through the BLCD panel 232 is transmitted through the A-coated surface and reflected on the B-coated surface. Incident on the projection lens 236 and the GLCD panel 23
G passing through 0 passes through all the coating surfaces of A and B and is incident on the projection lens 236, so that R,
All the color components of G and B are combined by the dichroic prism 234, and the light combined in this manner is transmitted to the projection lens 23.
After being incident on the screen 6, the image is formed on the screen S, and a rare image can be obtained.

[0044]

As described above, the three-panel LCD of the present invention is
The projector can improve the brightness of the image by making the red image and the blue image reflect on the basis of the S wave, and transmitting the green image on the basis of the P wave, particularly in the dichroic prism. In addition to this, there is an effect that the occurrence of a screen color difference can be eliminated by correcting the transmittance accompanying the difference in the incident angle in the gradient coating process.

[Brief description of the drawings]

FIG. 1 is a configuration diagram showing an optical path of an LCD projector to which the present invention is applied.

FIG. 2 is a configuration diagram showing a light path of a general LCD projector.

FIG. 3 is a schematic diagram of a main part showing an optical path of G;

FIG. 4 is an explanatory diagram showing a change in a characteristic curve with an incident angle, showing a shift to a long wavelength with a decrease in the incident angle and a shift to a short wavelength with an increase in the incident angle.

[Explanation of symbols]

100 lamp, 102 UV and heat light blocking mirror,
108 R reflection dichroic mirror, 110 G reflection dichroic mirror, 116 first reflection mirror, 12
0 Third reflection mirror, 128 RLCD panel, 130
GLCD panel, 132 BLCD panel, 134
Dichroic prism, 136 projection lens.

Claims (10)

[Claims] 1. An ultraviolet and heat light shielding mirror coated so as to block ultraviolet and heat light components of incident light emitted from a lamp in an LCD projector, and the ultraviolet and heat light shielding mirror And a first and second integrator lens for uniformly irradiating the beam, from which the ultraviolet light and the heat light are blocked, with the first and second integrator lenses.
An R reflection dichroic mirror that selectively reflects R from incident light evenly focused by the integrator lens, and a C-reflector based on Gradient and S-wave.
G reflection dichroic mirror that selectively reflects G (green) of S wave from the incident light transmitted through the R reflection dichroic mirror, and B (blue) transmitted through the G reflection dichroic mirror
A first and a second relay lens for compensating for a long optical path, and a first reflection mirror that is subjected to a gradient coating and reflects R (red) reflected from the R reflection dichroic mirror to the right, Second and third reflection mirrors disposed so as to be able to change the optical path of B transmitted through the G reflection dichroic mirror by 180 degrees, and the G reflection dichroic mirror and the first reflection mirror. First, for converging each R, G, B incident by the three reflection mirrors,
A few condenser lenses, and R focused through the first, second and third condenser lenses,
In order to allow G and B to form respective images, a polarizer coated on the basis of the S wave and a polarizer 228b coated on the basis of the P wave are provided in front of the liquid crystal. R, G, and BLCD panels each having a combination of an analyzer coated on the basis of the S wave and an analyzer coated on the basis of the P wave. A dichroic prism that combines the images formed by the G and BLCD panels into one image, and a projection lens that enlarges the image combined by the dichroic prism into one image and projects a screen. An optical system for an LCD projector. 2. The ultraviolet and heat light shielding mirror is 200 to 200.
More than 99% is reflected at a wavelength of 400 nm, 42
50% transmission and reflection at a wavelength of 0 nm;
2. The optical system for an LCD projector according to claim 1, wherein a coating process is performed so that 97% or more is transmitted at a wavelength of 30 to 660 nm. 3. The R-reflecting dichroic mirror transmits 97% or more of light incident at 45 degrees at a wavelength of 400 to 570 nm, and transmits 50% at a wavelength of 580 nm.
2. The optical system of an LCD projector according to claim 1, wherein the coating is performed such that each is reflected and transmitted, and at least 99.9% is reflected at a wavelength of 590 to 720 nm. 4. The G reflection dichroic mirror is such that 97% or more of incident light incident at 45 degrees is transmitted at a wavelength of 400 to 490 nm and 5% at a wavelength of 515 nm.
2. The optical system of an LCD projector according to claim 1, wherein a coating process is performed so that 0% is transmitted and reflected, respectively, and 99% or more is reflected at a wavelength of 520 to 650 nm. 5. The polarizer 228b has an incident light of 580 nm.
0.1% or less is transmitted at the following wavelengths and 590n
50% transmitted at a wavelength of m, 600-700n
2. The LC according to claim 1, wherein the coating is performed so that at least 94% of the light is transmitted at a wavelength of m.
Optical system for D projector. 6. A polarizer coated on the basis of the S wave transmits 0.1% or less of the incident light at a wavelength of 495 nm or less and transmits 5% of the incident light at a wavelength of 515 nm.
0% is transmitted and 9 at wavelengths of 525-555 nm.
4% or more transmitted, 50% at 560 nm wavelength
At a wavelength of 575 to 680 nm.
2. An optical system for an LCD projector according to claim 1, wherein the coating system is coated so that less than 0.1% is transmitted. 7. The polarizer 232b has an incident light of 380 nm.
0.1% is transmitted at the following wavelengths, 50% is transmitted at a wavelength of 390 nm, 97% or more is transmitted at a wavelength of 400-500 nm, 50% is transmitted at a wavelength of 510 nm, and 530-670 nm. 2. An optical system for an LCD projector according to claim 1, wherein a coating process is performed such that 0.1% or less of the light is transmitted. 8. The surface A of the dichroic prism is 45
0.1% or less is transmitted at a wavelength of 570 nm or less, and 5% at a wavelength of 585 nm.
0% is transmitted and 8 at a wavelength of 600-700 nm.
2. The optical system for an LCD projector according to claim 1, wherein a coating process is performed so that at least 5% of the light is transmitted. 9. The B surface of the dichroic prism is 45
85% or more is reflected at a wavelength of 400 to 500 nm, 50% is reflected at a wavelength of 520 nm, and 1% is reflected at a wavelength of 530 nm or more.
The optical system of an LCD projector according to claim 1, wherein a coating process is performed so that the following is transmitted. 10. The dichroic prism according to claim 1, wherein the surfaces A and B are coated so that 85% or more of the horizontally incident light is transmitted at a wavelength of 480 to 620 nm. LCD projector optical system.