JPH075410A - Liquid crystal projector - Google Patents

Abstract

PURPOSE:To improve the picture quality such as colors of a color image and obtain an excellent composite image by providing a converting member which changes the direction of polarized light on the incidence or projection side of a liquid crystal display panel. CONSTITUTION:Respective liquid crystal display panels 2-4 for red. green, and blue which are arranged nearby a dichroic prism 1 are all placed in the same polarization state, namely, the transmission axes of respective polarizing plates are all set to the direction of S-polarized light; and a wavelength plate 14 is arranged on the projection side of the liquid crystal display panel 3 for green. Consequently, the light from a light source 5 is divided by dichroic mirrors 6 and 7 and total reflecting mirrors 8-12 into three kinds of red, green. and blue to only irradiate the respective liquid crystal display panels 2-4. Therefore, the need to divide the light from the light source 5 into a P-polarized light component and an S-polarized light component and irradiate the respective liquid crystal display panels 2-4 is eliminated, the optical paths from the light source 5 to the respective optical display panels 2-4 are made simple, and restrictions on the optical path design are reduced to facilitate the optical path design and increase the degree of freedom.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a liquid crystal projector for projecting an image displayed on a liquid crystal display panel.

[0002]

2. Description of the Related Art Conventionally, light from a light source is divided into light of three wavelengths of red, green and blue, and the liquid crystal display panel for each color is irradiated with the light.
As a liquid crystal projector that displays an image on each of the liquid crystal display panels and synthesizes the image into a color image and projects the image, for example, as shown in
There is one configured as shown in.

In this type of liquid crystal projector, red, green, and blue liquid crystal display panels 2 to 4 are arranged in the vicinity of the dichroic prism 1, and light from a light source 5 is dichroic mirrors 6 and 7 and total reflection. Mirrors 8-12 are red, green,
The liquid crystal display panel 2-4 is irradiated with the light of each wavelength divided into three kinds of blue wavelength light, and the image of each color displayed on each liquid crystal display panel 2-4 is dichroic prism 1. A color image is combined, and the combined color image is projected by a projection lens 13 onto a screen (not shown) or the like.

That is, as for the light from the light source 5, only the light of the blue wavelength is transmitted through the dichroic mirror 6 and the other light is reflected. The blue wavelength light that has passed through the dichroic mirror 6 is sequentially reflected by the total reflection mirrors 8 to 10 and is applied to the blue liquid crystal display panel 4. Further, the light other than the blue wavelength reflected by the dichroic mirror 6 is applied to the dichroic mirror 7 via the total reflection mirror 11.
This dichroic mirror 7 transmits red wavelength light and reflects green wavelength light. The red wavelength light that has passed through the dichroic mirror 7 is reflected by the total reflection mirror 12 to irradiate the red liquid crystal display panel 2, and the green wavelength light reflected by the dichroic mirror 7 is totally reflected. The light is reflected by the mirror 8 and is irradiated onto the liquid crystal display panel 3 for green.

Further, each of the liquid crystal display panels 2 to 4 irradiated with light of each wavelength in this manner displays an image corresponding to each color, and liquid crystal is sealed between a pair of transparent electrode substrates. Polarizing plates are provided on both sides of the liquid crystal cell, and when light of each wavelength is irradiated, light of an image of each color enters the dichroic prism 1.

The dichroic prism 1 is for synthesizing an image by reflection and transmission. Two dichroic surfaces 1a and 1a made of a vapor deposition film are provided inside to intersect each other in an "x" shape, and two dichroic surfaces 1a, 1a reflects the light of the image displayed on each of the red and blue liquid crystal display panels 2 and 4, and also has two dichroic surfaces 1a,
Light of the image displayed on the liquid crystal display panel 3 for green is transmitted through 1a, so that each image is combined with a color image.

[0007]

2. Description of the Related Art The dichroic prism 1 of such a liquid crystal projector has an internal dichroic surface 1
a and 1a efficiently reflect light of S polarization component (linear polarization component horizontal to dichroic surface, the same applies below), and P polarization component (linear polarization component in a direction orthogonal to the S polarization component, and so on) ), The dichroic prism 1 has a characteristic of efficiently transmitting the light. Therefore, when all the lights emitted from the liquid crystal display panels 2 to 4 have the same polarization direction, that is, either the S polarization or the P polarization. Due to the above characteristics, good efficiency cannot be obtained. Therefore, the spectral transmittance on each of the dichroic surfaces 1a, 1a of the dichroic prism 1 has the characteristic shown in FIG. That is,
The red wavelength band R rises from around 500 nm to around 550 nm, light of wavelengths shorter than that is reflected, and light of longer wavelengths can be transmitted. Also, the blue wavelength band B is from 600 nm to 550 nm.
It stands up in the vicinity, and light of wavelengths longer than that is reflected, and light below it can be transmitted. Therefore, the band G through which the light of the green wavelength is transmitted becomes a band through which both the red wavelength and the blue wavelength are transmitted, and these bands do not overlap each other and do not overlap with each other. Band R of
If G and B are deviated, there is a problem that the image quality such as the color of the color image combined by the dichroic prism 1 is immediately deteriorated.

Further, in order to solve such a problem,
Of the liquid crystal display panels 2 to 4 for red, green, and blue, the dichroic surfaces 1a and 1a of the dichroic prism 1 are used.
A liquid crystal display panel 3 for green that displays an image that passes through
The transmission axes of the respective polarizing plates for the red and blue liquid crystal display panels 2 and 4 for displaying the image reflected by the dichroic surfaces 1a and 1a are set to P-polarized light and S-polarized light so that the dichroic prism 1 It may be possible to match the characteristics, but in such a case, there are the following problems. That is, when the transmission axes of the polarizing plates on the emission side of the liquid crystal display panels 2 to 4 are matched with the characteristics of the dichroic prism 1, the light incident on the polarizing plates on the incident side of the liquid crystal display panels 2 to 4 is red. In addition to the wavelengths of green, green, and blue, the liquid crystal display panels 2 to 3 are also considered in consideration of the characteristics of the dichroic mirrors for the light of the polarization components of the P polarization component and the S polarization component.
4, for example, a liquid crystal display panel 3 for green light of P-polarized component
First, it is necessary to irradiate the red and blue liquid crystal display panels 2 and 4 with the light of the S-polarized component. Therefore, the light source 1
To the liquid crystal display panels 2 to 4 become complicated,
There are many restrictions on the optical path design, and there is a problem that the optical path design is troublesome.

[0009]

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned circumstances, and an object of the present invention is not to make an optical path complicated and to have a high degree of freedom in designing an optical path, and to make boundaries between wavelength bands mutually Each band can be widened by overlapping.
Accordingly, it is an object of the present invention to provide a liquid crystal projector capable of improving the image quality such as the color of a color image and obtaining a good composite image.

[0010]

In order to achieve the above object, the present invention provides a liquid crystal display panel for displaying an image which is transmitted through the dichroic surface in the dichroic prism among the liquid crystal display panels arranged in the vicinity of the dichroic prism. Alternatively, a conversion member that changes the direction of polarized light is provided on either the incident side or the emission side of the liquid crystal display panel that displays the image reflected by the dichroic surface, and the light incident on the dichroic prism from the liquid crystal display panel is provided by this conversion member. The main point is that the polarization state on the emission side of each liquid crystal display panel is adjusted to the characteristics of the dichroic prism by changing the polarization direction of the liquid crystal display panel.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to FIGS. In this case, the same parts as those in the conventional example described above are designated by the same reference numerals, and the description thereof will be omitted. Figure 1
Shows the structure of the liquid crystal projector of the present invention. This liquid crystal projector includes liquid crystal display panels 2 to 4 for red, green, and blue in the vicinity of the dichroic prism 1 as in the above-described conventional example, and diverts light from a light source 5 to dichroic mirrors 6 and 7. The total reflection mirrors 8 to 12 divide the light into three kinds of wavelength light of red, green, and blue, and irradiate each of the divided light of each wavelength to each liquid crystal display panel 2 to 4, and each liquid crystal display panel 2 to 4 The displayed images of the respective colors are combined into a color image by the dichroic prism 1, and the combined color image is projected by the projection lens 13. In particular, on the exit side of the liquid crystal display panel 3 for green. A wave plate 14 that changes the polarization direction is provided.

In this case, each of the liquid crystal display panels 2 to 4 is of a normally black type, and the transmission axes of the polarizing plates provided on both sides of the liquid crystal cell are formed in the same direction on the incident side and the emitting side. Therefore, the transmission of light is blocked in a non-driving state where no voltage is applied, and conversely, the light is transmitted in a driving state where a voltage is applied. Moreover, in each liquid crystal display panel 2-4, since the transmission axis of each polarizing plate is formed in the direction of S polarization with respect to the dichroic surfaces 1a, 1a, all the light emitted from each liquid crystal display panel 2-4. It becomes an S-polarized component.

The wave plate 14 provided on the emission side of the liquid crystal display panel 3 for green is a 1 / 2λ plate that changes the direction of the polarization axis by 90 degrees, and its optical axis is the transmission axis of the polarization plate on the emission side. for
It is arranged at an angle of 45 degrees, and by transmitting light there,
The light of S polarization component is converted to the light of P polarization component with respect to the dichroic surface emitted from the liquid crystal display panel 3.

Therefore, according to the liquid crystal projector thus constructed, each of the red, green, and blue liquid crystal display panels 2 disposed near the dichroic prism 1 is provided.
Since all 4 have the same polarization state, that is, the transmission axes of the respective polarizing plates are all in the direction of S polarization, and the wave plate 14 is arranged on the emission side of the liquid crystal display panel 3 for green, It suffices to divide the light into three types of red, green and blue by the dichroic mirrors 6 and 7 and the total reflection mirrors 8 to 12 and irradiate each of the liquid crystal display panels 2 to 4. Therefore, the light source 5
Since it is not necessary to divide the light from the P polarization component and the S polarization component and irradiate each of the liquid crystal display panels 2 to 4, the optical path from the light source 5 to each of the liquid crystal display panels 2 to 4 becomes simple, and the optical path design is performed. There are few restrictions above, the optical path design is easy, and the degree of freedom is high.

Particularly, among the liquid crystal display panels 2 to 4, the dichroic surfaces 1a and 1a of the dichroic prism 1 are provided.
Since the wavelength plate 14 is arranged on the emission side of the green liquid crystal display panel 3 that displays an image that transmits light, even if light of the S-polarized component is emitted from this liquid crystal display panel 3, the direction of polarization of light is changed by the wavelength plate 14. Can be changed by 90 degrees to convert S-polarized light into P-polarized light. Therefore, the polarization state of each light entering the dichroic prism 1 from each of the liquid crystal display panels 2 to 4 can be matched with the characteristics of the dichroic prism 1. That is, in the dichroic prism 1, the internal dichroic surfaces 1a and 1a efficiently reflect the light of the S-polarized component,
Further, it has a characteristic of efficiently transmitting the light of the P-polarized component, and the light of the S-polarized component is emitted from each of the red and blue liquid crystal display panels 2 and 4 for displaying the image reflected by the dichroic surfaces 1a and 1a. Incident and dichroic surface 1
Even if the S-polarized component light is emitted from the green liquid crystal display panel 3 that displays an image that transmits a and 1a, the polarization direction is converted by 90 degrees by the wave plate 14 as described above, and the P-polarized component It becomes light, which enters the dichroic prism 1. As a result, the polarization states of the liquid crystal display panels 2 to 4 and the characteristics of the dichroic prism 1 can be matched.

As described above, when the polarization states of the liquid crystal display panels 2 to 4 and the characteristics of the dichroic prism 1 match, the dichroic surface 1 of the dichroic prism 1 will be described.
As shown in FIG. 2, the spectral transmittances of a and 1a show different characteristics between the S-polarized light and the P-polarized light on the dichroic surfaces 1a and 1a.

First, in the case of S-polarized light, in the case of the red wavelength, the boundary R _{1 of the} band R rises sharply near 600 nm, the upper end thereof does not reach 100% transmittance, and the blue at low position. Since it extends toward the wavelength band B, the reflected band R becomes wider and the reflectance becomes higher. Further, in the case of the blue wavelength, the boundary B _{1 of the} band B rises sharply around 500 nm, and the upper end thereof does not reach the transmittance of 100% as described above,
Since it extends to the red wavelength band R side at a low position, the band B to be reflected is wide and the reflectance is high as in the above case. For this reason, the red wavelength band and the blue wavelength band are respectively widened in the reflection bands R and B, and are efficiently reflected by the dichroic surfaces 1a and 1a, but the green wavelength reflection band G is narrowed, and the reflectance is poor.

Next, the case of P-polarized light will be described. In the red wavelength in this case, the boundary R _{2 of the} band R rises sharply near 630 nm and the upper end reaches 100% transmittance, so the band R of the red wavelength to be transmitted is narrow at 630 nm or more, and the transmittance is Low. In the case of the blue wavelength, the boundary B of the band B
₂ rapidly rises near 470 nm, and its upper end reaches 100% transmittance in the same manner as described above. Therefore, the band B of the blue wavelength to be transmitted is also narrow at 470 nm or less, and the transmittance is low. Therefore, the band G of the transmitted green wavelength is a region surrounded by the boundaries R ₂ and B ₂ in the transmission of the red wavelength and the blue wavelength, and is surrounded by the boundaries R ₁ and B ₁ in the reflection of the red wavelength and the blue wavelength. It is wider than the area.

As a result, the red wavelength band R and the blue wavelength band B reflected by the dichroic surfaces 1a and 1a and the green wavelength band G transmitted through the dichroic surfaces 1a and 1a are as shown in FIG. Since the boundaries thereof overlap each other and are overlapped with each other, they are wider than the conventional one shown in FIG. 4, and even if the wavelength bands R, G, and B are deviated due to manufacturing errors, It is possible to obtain a good composite image without deteriorating the image quality such as color.

In the above-mentioned embodiments, the S-polarized type (one in which the transmission axis of each polarizing plate is provided in the S-polarized direction with respect to the dichroic surface) is used as each of the liquid crystal display panels 2 to 4. The liquid crystal display panel of P polarization type (the one in which the transmission axis of each polarizing plate is provided in the direction of P polarization) may be used, and in this case, the liquid crystal display panels 2 for red and blue, 4 only on the output side of the wave plate 14
Should be provided respectively. In addition, each liquid crystal display panel 2
No. 4 is not limited to the normally black type, but a normally white type may be used, and the method may be a simple matrix method or an active matrix method using a TFT (thin film transistor). Good.

The wave plate 14 is a liquid crystal display panel 2-4.
The conversion member for changing the direction of polarized light is not limited to the wave plate 14 and may be provided on the incident side, and may be provided on the incident side, and a liquid crystal panel having no display function is used. The direction may be changed.

[0022]

As described in detail above, according to the liquid crystal projector of the present invention, an image transmitted through the dichroic surface in the dichroic prism among the liquid crystal display panels arranged in the vicinity of the dichroic prism is displayed. A conversion member that changes the direction of polarized light is provided on either the incident side or the emission side of the liquid crystal display panel that displays the image reflected by the dichroic surface. By changing the polarization direction of the light entering the prism, the polarization state on the exit side of each liquid crystal display panel can be matched to the characteristics of the dichroic prism, so the optical path is not complicated and the degree of freedom in optical path design is increased. It is possible to spread each band by overlapping the boundaries of each wavelength band with each other. Bets can be, thereby increasing the quality of such color image color, it is possible to obtain a good composite image.

[Brief description of drawings]

FIG. 1 is a configuration diagram of a liquid crystal projector according to an embodiment of the present invention.

FIG. 2 is a diagram showing spectral characteristics on a dichroic surface of the dichroic prism.

FIG. 3 is a configuration diagram of a conventional liquid crystal projector.

FIG. 4 is a diagram showing a conventional spectral characteristic.

[Explanation of symbols]

 1 Dichroic prism 1a Dichroic surface 2-4 Liquid crystal display panel 5 Light source 6, 7 Dichroic mirror 8-12 Total reflection mirror 14 Wave plate

Claims (1)

[Claims] 1. A light from a light source is split into light of each wavelength of red, green, blue, etc., and the light is applied to a liquid crystal display panel for each color, and each image displayed on the liquid crystal display panel for each color is dichroic prism. In a liquid crystal projector that performs composite projection by reflection and transmission on a dichroic surface inside, a liquid crystal display panel that displays an image that is transmitted through the dichroic surface inside the dichroic prism among the liquid crystal display panels, or is reflected on the dichroic surface. A liquid crystal projector, characterized in that a conversion member for changing the polarization direction of light is provided on either the incident side or the emission side of a liquid crystal display panel for displaying an image.