JPH04207773A - Liquid crystal projection type television - Google Patents

Abstract

PURPOSE:To enhance the utilization efficiency of light and to comply with a large-sized screen by providing optical element parts which synthesizes and projects light beams transmitted through 1st and 2nd liquid crystal panels and projecting the light beams transmitted through the 1st and the 2nd liquid crystal panels to the same position by using the optical element parts. CONSTITUTION:Out of the light beams R, G and B from a lamp 11, only the light beam B reflected by a diachronic mirror 13a is fetched. Since all the picture elements of the single liquid crystal panel 15 are for the modulation of the light beam B, the light beam B is projected from the panel 15 as it is and projected to a screen 17. Meanwhile, the color filter of a color liquid crystal panel 14 is constituted of halves of the colors R and G, so that the light beams R and G become R/2.G/2 when they are projected from the panel 14. Therefore, the intensity of respective colors R, G and B becomes 1/2.1/2.1 on the screen 17, and the ratio of R:G:B becomes 1:1:2. The utilization factor of the light beam is enhanced, and the ratio of the light of specified wavelength, in this case, the light beam B is enhanced.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to a liquid crystal projection television that enlarges and projects images displayed on a liquid crystal panel onto a screen.

BACKGROUND OF THE INVENTION In recent years, liquid crystal projection televisions, which enlarge and project images displayed on a small liquid crystal panel using a projection lens or the like to obtain a large screen image, have been attracting attention and are being actively researched and developed. LCD projection TVs can provide a large screen even with a small LCD panel.

■The same resolution as the direct view type can be obtained with 1/3 the number of images.

■There is no viewing angle problem, which is a drawback of direct-view LCD panels.

■It is smaller and lighter than the cathode ray tube (hereinafter referred to as CRT) type. It has many characteristics such as

Hereinafter, a conventional liquid crystal projection television will be described with reference to the drawings. FIG. 7 is a block diagram of a conventional liquid crystal projection television. Note that components unnecessary for explanation, such as field lenses, are omitted in the drawings. The above also applies to the following drawings and descriptions. As shown in FIG. 7, its components include a light source 71 consisting of a halogen lamp, a concave mirror, a condensing lens system, etc., a projection lens system 73, a screen 74, and a liquid crystal panel 72 with a color filter. A more detailed configuration diagram of the liquid crystal panel is shown in FIG. FIG. 8 is a sectional view of a liquid crystal panel with color filters. In FIG. 8, 21a and 21b are polarizing films and 22a.

22b is a glass substrate, 81 is a color filter, 82 is a top coat layer coated to smooth unevenness on the color filter, 23 is a counter electrode made of a transparent electrode (hereinafter referred to as ITO), and 24 is a twisted nemastech , 25 is a pixel electrode of each pixel, and 26 is wiring such as a source signal line. Note that blank matrices and the like that are unnecessary for the explanation are omitted from the drawings. FIG. 9 is a layout diagram of red (hereinafter referred to as R), green (hereinafter referred to as G), and blue (hereinafter referred to as B) as color elements of the color filter. Corresponding to each pixel, 1/3 of the whole is R, 1/3
is G1 and the remaining 1/3 is B, which is arranged in delta.

The optical path will be described below with reference to FIGS. 7 and 8.

First, light emitted from the light source 71 is collected by a concave mirror and a condensing lens system, and becomes parallel light and enters the liquid crystal panel 72. The light becomes linearly polarized by the polarizing film 21a placed on the incident light side of the liquid crystal panel 72, and only the R, G, and H lights are transmitted by the color filter 81. A voltage is applied to each pixel electrode 25 in accordance with a video signal, and an electric field is applied to the liquid crystal layer 24 on the pixel electrode 25, so that light is modulated. The modulated light passes through the polarizing film 21b according to the degree of modulation, is focused by the projection lens 73, and is enlarged and projected onto the screen 74.

Next, the drive circuit system will be explained. FIG. 10 is an explanatory diagram of the drive circuit system. As shown in FIG. 10, the components R1 and R2 are resistors, Q is a transistor,
Resistors R1, R2 and transistor Q constitute phase dividing circuits 102a, 102b, and 102c that generate video signals of positive polarity and negative polarity of the video signal input to the base terminal. Reference numerals 101a, 101b, and 101c are output switching circuits that apply AC video signals whose polarities are inverted for each field to the liquid crystal panel. As for the circuit operation, each video signal R-G-B is gain-adjusted to a predetermined value, and the phase dividing circuits 102a, 102b, 102c
is input. Two video signals of positive polarity and negative polarity are created here, and the next output switching circuits 101a and 101b are
.

101c. Output switching circuit 101a.

101b and 101c perform timing adjustment and the like, and then apply a video signal to the liquid crystal panel 62 from the output terminal. At this time, the polarity of the signal voltage applied to each pixel is reversed for each field. The reason why the polarity of the voltage is switched in this way is that the liquid crystal will decompose and deteriorate if it is not driven with alternating current. In the liquid crystal panel, a source drive IC (not shown) is controlled by a control circuit (not shown).
and a gate drive Ic (not shown), and an image is displayed on the liquid crystal panel.

Problems to be Solved by the Invention Conventional liquid crystal projection televisions use a single liquid crystal panel with a color filter. Therefore, a color filter corresponding to the R color transmits only the R light, and the B and G parts become heated. Similarly, the color filter on the B color pixel turns the G and R light into heat, and the color filter on the G color pixel turns the R and B light into heat. Therefore, the light utilization rate is extremely low. Further, taking a liquid crystal panel with 90,000 pixels as an example, if each pixel is broken down into RGB, there are only 30,000 pixels each, which is extremely poor screen resolution. Moreover, when the light source is a halogen lamp, for example, the wavelength component of the light is that the R light component is very strong and the B light component is almost absent. As a result, the color temperature of the displayed image becomes extremely low, causing the image to become reddish and resulting in a reduction in image quality.

The present invention takes the above-mentioned problems into consideration and aims to provide a liquid crystal projection television that has high light utilization efficiency and improved color temperature.

Means for Solving the Problems In order to solve the above problems, a liquid crystal projection television according to a first aspect of the present invention includes a liquid crystal panel with a color filter, a liquid crystal panel without a color filter, and a projection optical lens. It is something.

Further, the liquid crystal projection television of the second aspect of the present invention includes first and second liquid crystal panels with color filters and a projection optical lens, and the first liquid crystal panel has two of R, G, and B.
Color filters for one color element are formed on the second liquid crystal panel, and color filters for the remaining color elements are formed on the second liquid crystal panel.

Function: In the liquid crystal projection television of the first aspect of the present invention having the above configuration, by providing a second liquid crystal panel that does not have a color filter, brightness modulation is performed exclusively, and the first liquid crystal panel is used to perform color signals. The light from the lamp is combined with a dichroic mirror to R-
One of the G-B color elements is taken out, modulated by a first liquid crystal panel without a color filter, and projected onto a screen. On the other hand, the remaining two color elements are guided to a liquid crystal panel having color filters and modulated. Further, the liquid crystal projection television of the second aspect of the present invention is provided with a second liquid crystal panel dedicated to only one color that is insufficient in terms of brightness, and the remaining first liquid crystal panel is provided with color filters for the remaining two colors, This is used to synthesize the light from the lamp, and it also converts the light from the lamp into a half mirror.
The light is separated into two optical paths, one of which is guided to a first liquid crystal panel having a color filter for one color element, and the other to a second liquid crystal panel having color filters for the remaining color elements for modulation. As described above, by configuring as in the first and second aspects of the invention, the utilization rate of light is improved and a high-brightness screen can be obtained. Furthermore, when a halogen lamp is used as a light source, the R light is very strong and the B light component is very small. Therefore, as in the first invention, only the B light is taken out by a dichroic mirror and modulated by a dedicated first liquid crystal panel. Alternatively, by modulating the light separated by a half mirror with a first liquid crystal panel dedicated to B light, it is possible to increase the amount of B light projected onto the screen.

EXAMPLE Hereinafter, a liquid crystal projection television according to the first aspect of the present invention will be explained with reference to the drawings. FIG. 1 is a block diagram of a liquid crystal projection television according to an embodiment of the first invention. Note that, as described in the description of the conventional example, parts unnecessary for the description are omitted. The same applies to the following drawings. As shown in FIG. 1, its components are: 11 a light source consisting of a lamp, a concave mirror, and a condensing lens system; 16 a projection lens system; 17 a screen; 13a and 13b dichroic mirrors;
12a and 12b are total reflection mirrors, 14 is a liquid crystal panel with a color filter (hereinafter referred to as a color liquid crystal panel), 15
is a liquid crystal panel without a color filter (hereinafter referred to as a mono liquid crystal panel). The mono liquid crystal panel 15 is shown in more detail in FIG. FIG. 2 is a sectional view of a mono liquid crystal panel.

Further, the configuration of the color liquid crystal panel is the same as the configuration shown in FIG. 8 except that there is no color filter, so the explanation will be omitted. However, the arrangement of color filters on pixels is R-
Color filters of two primary colors among the three primary colors G-B are formed. That is, in the example of FIG. 3 (C2), 1/2 is R1 and the remaining 1/2 is G.

To simplify the explanation, it is assumed here that the lamp is a halogen lamp, and the configuration of the color filter of the color liquid crystal panel 14 is shown in FIG. 3 (C2). Furthermore, the dichroic mirror 13a reflects B light, and the dichroic mirror 13b reflects R and G light. Furthermore, the mono liquid crystal panel 15 is shown in FIG. 3 (al). However, in FIG. 3(al), a B color filter is not formed, but it means that B light is incident and all pixels are used for modulating the B light. Similarly, the third
Figure (bl) shows that all pixels are used for modulating R light, and Figure 3 (C1) shows that all pixels are used for modulating G light.

As mentioned earlier, halogen lamps contain a large amount of R light,
The component of B light is small. Therefore, only the B light is extracted from the lamp light by the dichroic mirror 13a. This B
The light is guided to the mono liquid crystal panel 15, and the polarizing film 21a
It becomes linearly polarized light. This polarized light is modulated in the liquid crystal layer 24 according to the signal applied to the liquid crystal panel, passes through the polarizing film 21b and the dichroic mirror 13b according to the degree of modulation, and is enlarged and projected onto the screen 17 by the projection lens system 16. Ru. On the other hand, the RG light transmitted through the dichroic mirror 13a is guided to the color liquid crystal panel 14 having the configuration shown in FIG. 8, and is converted into linearly polarized light by the polarizing film 21a. This polarized light is modulated according to the signal applied to the liquid crystal panel, and is transmitted through the polarizing film 21b according to the degree of modulation. At this time, the light is as shown in Figure 3 (C2).
With the color filter configured as follows, R light passes through the R color pixel, and G light passes through the G color pixel. The light modulated in this manner is reflected by the dichroic mirror 13b, and is enlarged and projected onto the screen 17 by the projection lens 16. At this time, the mono liquid crystal panel 15 and the color liquid crystal panel 1
The projected images No. 4 are projected at the same position on the screen 17, and a color image is displayed.

Here we will discuss the ratio and intensity of light projected onto the screen. For ease of explanation, (2) The proportion of RGB light from the lamp 11 is constant. ■Light is not lost in guichroic mirrors, liquid crystal panels, and polarizing films. ■There is no loss even with color filters, and only the color of the color filter on the pixel is transmitted. In the liquid crystal projection television according to the embodiment of the first invention, the light R from the lamp 11 is:
For G-B, only the B light reflected by the dichroic mirror 13a is taken out, and this B light is sent to the mono liquid crystal panel 15.
Since all the pixels are for B light modulation, they are emitted as they are from the mono liquid crystal panel 15 and projected onto the screen 17.

On the other hand, since the color filter of the color liquid crystal panel 14 is composed of 1/2 of each of the R and G colors, the RG light becomes R/2 and G/2 when the color liquid crystal panel 14 emits the light.

Therefore, on the screen 17, the intensities of each color R-G-B are 1/2, 1/2, and 1, and the ratio of RAGB is 1:
The ratio will be 1:2.

As described above, the present invention has a higher light utilization rate than the conventional example, and can increase the ratio of light of a specific wavelength, here B destination.

Therefore, the color temperature can be improved and the image quality can be significantly improved compared to the conventional method. Next, when the lamp 11 is a metal halide lamp, the R light component is generally small. Therefore, as shown in FIG. 3(bl), the mono liquid crystal panel 15 is
For light modulation, B and G color filters are formed on the pixels of the color liquid crystal panel 14 as shown in FIG. 3 (b2).
It is configured for modulating B-G light. Naturally, in the configuration diagram of FIG. 1, the dichroic mirror 13a is an R light reflecting mirror, and the dichroic mirror 13b is a B
- G light reflecting dichroic mirror. When configured as described above, the strength of each color R, G-B is 1, 1/2, 1/2
Therefore, the ratio of RG:B is 2:11. Therefore, the utilization efficiency of R light can be increased, and the color temperature can be improved. If you want to improve the resolution, use the mono liquid crystal panel 15 for G light modulation as shown in Figure 3 (C1), and use the color liquid crystal panel 14 for R light modulation as shown in Figure 3 (C2). B color filter is formed, R-G-
It is configured for modulation of destination B. Naturally, in the configuration shown in FIG. 1, the dichroic mirror 13a is a G-light reflecting dichroic ink mirror, and the dichroic mirror 13b is an R-B light reflecting dichroic mirror. The reason why the mono liquid crystal panel 15 is used for G light modulation is that the image is a video signal G.
This is because the resolution is approximately determined by the components. If the R-G-H color balance is poor in the liquid crystal projection television of the first aspect of the present invention, a color correction color filter or a dark filter is inserted on the incident side of the liquid crystal panel to maintain the balance.

Hereinafter, a driving circuit system and a driving method for a liquid crystal projection television according to an embodiment of the first and second inventions to be described later will be described. FIG. 4 is an explanatory diagram of a drive circuit system and a drive method. As shown in Figure 4, its constituent elements are 41
a, 41b, 41c are phase division circuits, 42a, 42b,
42c is an output switching circuit. Further, the output of the output switching circuit 42a is input to the mono liquid crystal panel 15, and the output of the output switching circuits 42b and 42c is input to the color liquid crystal panel 14. For ease of explanation, the video signal (A) is assumed to be a color video signal, the video signal (B) is assumed to be a G color video signal, and the video signal (C) is assumed to be an R color video signal. As for the operation of the circuit, the video signals of each BGR color are gain-adjusted to a predetermined value, and the phase dividing circuit 4
1a, 41b.

41c. Here, signals of positive polarity and negative polarity are generated, and these signals are sent to the output switching circuit 42a.

42b and 42c. Here, the polarity of the signal is switched for each field and applied to the liquid crystal panels 14 and 15. FIGS. 5(a 1) and 5(a 2) show the polarity states of the voltages applied to the pixels of each liquid crystal panel. Here, - indicates a voltage in the negative direction with respect to the voltage applied to the pixel or the voltage applied to the counter electrode, that is, the common voltage, and + indicates a voltage in the positive direction with respect to the common voltage. ing. In addition, FIG. 5 (al) shows the mono liquid crystal panel 1.
5 (C2) shows the polarity state of the voltage of each pixel of the color liquid crystal panel 14. Naturally, after one field or one frame, the polarity state of the voltage of the mono liquid crystal panel 15 is changed as shown in Fig. 5 (C
2), the polarity state of the voltage of the color liquid crystal panel 14 is the fifth
The state shown in figure (al) will be obtained. The two liquid crystal panels are projected at the same position on the screen. Therefore, the ten polar pixels of the mono liquid crystal panel 15 overlap at the same position as the mono polar pixels of the color liquid crystal panel 14. Therefore, normally, the voltage applied to the liquid crystal varies depending on the polarity of the voltage, which causes flicker, but in the present invention, since the unipolar and decapolar polarities are overlapped at the same position, the polarity of the flicker is opposite, canceling out the flickering. There is no origin. Driving by applying signals of opposite polarity to pixels adjacent to each other on the left and right sides in the vertical direction as described above will hereinafter be referred to as 1.inversion driving. Also, Fig. 5 (a 1),
(a 2) is 1■ inversion drive, but Fig. 5 (b 1
), (b2), signals of opposite polarity may be applied to the vertically adjacent pixels in the horizontal direction to drive them.

Here, FIG. 5(bl) shows the polarity state of the voltage of the mono liquid crystal panel 15 at a certain time, and FIG. 5(b2) shows the polarity state of the color liquid crystal panel. Naturally, after one field or one frame, the polarity state of the voltage on the mono liquid crystal panel 15 becomes as shown in FIG. 5 (b2), and the polarity state of the voltage on the color liquid crystal panel 14 becomes as shown in FIG. 5 (bl). .

Such a driving method will hereinafter be referred to as IH inversion driving. In addition,
By combining IV inversion drive and IH inversion drive, flicker can be further reduced. Further, by forming an optical image on the screen in consideration of the scanning directions of the two liquid crystal panels 14 and 15, it is possible to offset and reduce the brightness gradient. This consideration means that when scanning to form an optical image of the mono liquid crystal panel 15 is performed from the top edge of the screen, scanning to form an optical image of the color liquid crystal panel 14 is performed from the bottom edge of the screen. It is to do so. This can be easily realized by using a field memory or the like.

Hereinafter, a liquid crystal projection television according to an embodiment of the second invention will be described with reference to the drawings. FIG. 6 is a block diagram of a liquid crystal projection television according to an embodiment of the second invention. In FIG. 6, 61 is a nof mirror. Also, 62
．． 63 is a color liquid crystal panel. The arrangement of color filters on pixels is shown in Figure 3 (a 1), (a 2), (b
1), (b 2), (c 1).

It is shown in (C2). In the description of the liquid crystal projection television according to the first embodiment of the present invention, FIGS.
1) has been described as a diagram in which no color filters are formed, but in this embodiment, it is assumed that color filters for each primary color are formed. Again, for ease of explanation,
The lamp is a halogen lamp, the color filter configuration of the color liquid crystal panel 63 is shown in FIG. 3 (al), and the color filter configuration of the color liquid crystal panel 62 is shown in FIG. 3 (C2). Further, the dichroic mirror 13a is a B light reflecting gicchroic mirror, the dichroic mirror 13b is a G-R light reflecting gicchroic mirror, and the half mirror 61 is a gicchroic mirror that reflects light from a light source by 1/2.
shall be divided into. As explained in the embodiment of the first invention, the halogen lamp has a large R light component and a small B light component. Therefore, it is necessary to effectively extract and modulate the B light. First, turn the light from the lamp into a half mirror 61.
The light is divided into 1/2 by 1/2, and one side is made incident on the color liquid crystal panel 63 for B light modulation, and the other side is made incident on the color liquid crystal panel 62 for R-G light modulation. The color liquid crystal panel 63 uses a color filter to transmit only B light, and modulates this B light in accordance with a signal applied to the liquid crystal layer. The modulated light passes through the polarizing film 21b according to the degree of modulation, passes through the microink mirror 13b, and is enlarged and projected onto the screen 17 by the projection lens 16. On the other hand, the color liquid crystal panel 6
Regarding the light incident on 2, either the R light is transmitted through the R color pixel, or the G light is transmitted through the G color pixel. This RG light is modulated according to the signal applied to the liquid crystal layer 24 as before.

The modulated light passes through the polarizing film 21b according to the degree of modulation, passes through the dichroic mirror 13b, and is enlarged and projected onto the screen 17 by the projection lens 16. At this time, the projected images of the color liquid crystal panel 62 and the color liquid crystal panel 63 are projected onto the same position on the screen 17, and a color image is displayed. Here, the intensity and ratio of RGB light under the conditions described in detail in the first invention will be described. The RGB light from the lamp is divided into 1/2 by a nof mirror 61. Therefore, 1/2 of the light is incident on each of the color liquid crystal panels 62 and 63. Since all pixels of the color liquid crystal panel 63 are for B light modulation, the output from the color liquid crystal panel 63 is B/2, and since the color liquid crystal panel 62 has 1/2 each of R and G color pixels, At the time of emission, it becomes R/4 and G/4. Therefore, on the screen, the strength of each color R-G-B is R/4・G
/4·B/2, and the ratio of R':G:B is 11.2. In other words, since the ratio of the specific wavelength, here B light, can be increased, the color temperature of the screen image can be improved and the image quality can be improved. In addition, when the lamp is a metal halide lamp, the color liquid crystal panel 63 is used for R light modulation as shown in FIG.
As shown in b2), a color liquid crystal panel 62 is used for B-G light modulation. Similarly, if you need resolution, use the third
The color liquid crystal panel 63 is used for G light modulation as shown in FIG. 3(C2), and the color liquid crystal panel 62 is used for R-B light modulation as shown in FIG. 3(C2). Incidentally, when the color balance is poor, adjustment can be made by varying the light separation ratio of the half mirror 61. An embodiment of the second invention uses color liquid crystal panels for both of the two optical paths. 1st
In the LCD projection type TV according to the embodiment of the present invention, one of the LCD panels does not have a color filter, so the conditions for creating a gap between the LCD panels cannot be made the same for the color LCD panel and the mono LCD panel, and the manufacturing conditions l However, the second aspect of the present invention is that color filters are attached to both liquid crystal panels in the liquid crystal projection television, so the manufacturing conditions for the liquid crystal panels can be the same, making manufacturing easier. Since this is the same as the first embodiment of the present invention, the explanation will be omitted.

In carrying out the present invention, the liquid crystal nozzle used is a Noist non-mastenck liquid crystal panel, but is not limited to this, and may be a polymer-dispersed liquid crystal nozzle in which droplet-like liquid crystal is encapsulated in a polymer, or liquid crystal molecules. A scattering mode liquid crystal panel (polymar
It goes without saying that a network 1quid crystal) may also be used.

Furthermore, although the liquid crystal panel is illustrated as having a polarizing film attached thereto, the present invention is not limited to this; for example, a polarizing film attached to a glass substrate may be used. Further, it goes without saying that the liquid crystal panel section may use a phase compensation panel or a phase compensation film.

Furthermore, although the light source has been described as a metal halide lamp or a /'v O-gen lamp, it is not limited thereto; for example, a xenon lamp may be used, and the number of light sources is not limited to one.

In addition, the two optical paths are combined into one by a guichroic mirror, and the image is projected onto the screen using one projection lens. Needless to say, it can be anything.

In this case, the guichroic mirror 13b is not necessary.

Further, although the LCD projection type television according to the first embodiment of the present invention is described as having no color filter attached to the mono LCD panel, it is also possible to form a monochromatic color filter in order to perform color correction. Needless to say.

Furthermore, although the liquid crystal panel used in the liquid crystal projection television of the present invention is expressed as being of a transmissive type, it is not limited to this, and it is clear that a reflective liquid crystal panel can be constructed in substantially the same manner.

Further, although the color elements formed on the color filter are three primary colors of R, G-B, the present invention is not limited to these, and may be, for example, magenta or magenta.

Further, in the present invention, one color element is modulated in the first liquid crystal panel and two color elements are modulated in the second liquid crystal panel, but the present invention is not limited to this. or R-G,
It goes without saying that an image may be formed by forming a color filter of one color element on the second liquid crystal panel and modulating the liquid crystal panel with light of two colors.

Effects of the Invention As is clear from the above explanation, the LCD projection type televisions of the first and second aspects of the present invention are equipped with two liquid crystal panels, one of which is used only for brightness modulation without providing a color filter. By using it for exclusive modulation of one color element, the light utilization efficiency is improved and R-G
- One primary color of the B light can be projected onto the screen more strongly than the other primary colors. Therefore, in the past, when a halogen lamp was used as a lamp, the image on the screen became reddish and the color temperature decreased, degrading the image quality.However, with the present invention, the color temperature can be improved and the image quality can be significantly improved. can be improved. Furthermore, when images from two liquid crystal panels are formed on a screen, the occurrence of flicker can be eliminated by making the signal polarities of the pixels of both liquid crystal panels stacked at the same position opposite to each other. can.

Furthermore, by using two liquid crystal panels, the resolution can be significantly improved. Furthermore, in the first aspect of the present invention, since one primary color light is separated from the R-G-B light using a guichroic mirror, the light utilization efficiency is very high, and it is significantly more efficient than the conventional method. It can display bright images and is compatible with larger screens.

[Brief explanation of the drawing]

Fig. 1 is a configuration diagram of a liquid crystal projection television according to an embodiment of the first invention, Fig. 2 is a cross-sectional view of a liquid crystal panel used in the embodiment, and Fig. 3 is a color filter color used in the embodiment. FIG. 4 is a block diagram for explaining the driving circuit system of the LCD projection television of the present invention according to the same embodiment, and FIG. 5 shows the state of pixels of the liquid crystal panel according to the same embodiment. A pattern diagram, FIG. 6 is a configuration diagram of a liquid crystal projection television according to an embodiment of the second invention, FIG. 7 is a configuration diagram of a conventional liquid crystal projection television, and FIG. 8 is a sectional view of a conventional liquid crystal panel. , FIG. 9 is a pattern diagram showing the color arrangement of a conventional color filter, and FIG. 10 is a pattern diagram showing the color arrangement of a conventional color filter.
The figure is a block diagram for explaining a drive circuit system of a conventional liquid crystal projection television. 11... Light source, 12a, 12b... Mirror, 13a, 13b... Guicroic mirror, 14... Liquid crystal panel with color filter, 1
5...Liquid crystal panel, 16...Projection lens system. Name of agent: Patent attorney Haruaki Ogata and 2 others Figure 2! 7b 27ri Figure 1 Figure 3 (/4) CB) Figure 3 (C) Figure 3 (ENCF) Figure 4 Figure 5 (, A) Figure 5 (K) CD) Figure 7 Figure 9

Claims (6)

[Claims] (1) a first liquid crystal panel having a color filter of one or more colors that modulates input light based on an input signal; a second liquid crystal panel that modulates the brightness of the input light based on the input signal; an optical element component that combines and projects light transmitted through the first and second liquid crystal panels, the optical element component comprising:
A liquid crystal projection television that projects light transmitted through the first and second liquid crystal panels at the same position. (2) a first liquid crystal panel that modulates the input light through color filters of multiple colors based on the input signal; and a first liquid crystal panel that modulates the input light through the color filter of one color based on the input signal. a second liquid crystal panel; and an optical element that projects the light that has passed through the first and second liquid crystal panels, and the optical element that projects the light that has passed through the first and second liquid crystal panels. An LCD projection television that projects images at the same location. (3) The light emitted from the light generating means is separated into first and second input lights by the dichroic mirror, the first input light being the input light of the first liquid crystal panel, and the second input light being the input light of the first liquid crystal panel. 3. The liquid crystal projection television set according to claim 1, wherein the input light is the input light of the second liquid crystal panel. (4) The light emitted from the light generating means is separated into first and second input lights by the half mirror, the first input light being the input light of the first liquid crystal panel, and the second input light being the input light of the first liquid crystal panel. 3. The liquid crystal projection television set according to claim 1, wherein the input light is the input light of the second liquid crystal panel. (5) The dichroic mirror separates the first input light consisting of two colors and the second input light consisting of one color other than the above two colors, and the multi-color color filter of the first liquid crystal panel 3. The liquid crystal projection television set according to claim 2, wherein the liquid crystal projection television is a two-color filter. (6) The liquid crystal projection television according to any one of claims 1 to 5, wherein the phase of the input signal to the first liquid crystal panel and the phase of the input signal to the second liquid crystal panel are opposite in phase.