JPH0876079A - Projection type color liquid crystal display device - Google Patents

Abstract

(57) [Summary] [Structure] The dichroic mirrors 9R, 9G, and 9B cause the light fluxes of red, green, and blue to enter the liquid crystal module 2 with microlenses from different directions, and the incident angles of the respective light fluxes with the microlenses. According to the above, the light is condensed on a pixel, and each light flux passing through each pixel is optically modulated and then combined on a screen to display in color. The mirror position detection sensor 19 detects the arrangement of the mirrors 9R, 9G, and 9B, and the liquid crystal video signals S _R , S _G , S to be supplied to each pixel according to the detection result.
Switch _B. [Effect] When the liquid crystal panel 12 has a green bright spot with high luminous brightness, the display quality is adversely affected. However, the mirrors 9G and 9B are exchanged so that the incident angles of the green and blue light beams are exchanged. Corresponding to, by switching the drive signal to the pixel that performs light modulation corresponding to each light flux, it is possible to change the green bright point to a blue bright point with low luminous brightness,
The display quality can be improved.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention irradiates a single liquid crystal display element with a plurality of light fluxes having different wavelength regions from different directions to optically modulate each light flux, and synthesizes these light fluxes to produce a color image. The present invention relates to a single-panel projection type color liquid crystal display device for displaying, and is particularly applied to a compact projection type color television (TV) system and information display system.

[0002]

2. Description of the Related Art Since a liquid crystal display element does not emit light by itself, it is necessary to provide a light source separately. However, a projection type color liquid crystal display device in which this liquid crystal display element is applied to a projection type color display device is a projection type cathode ray tube. Compared with the display device,
It has a wide range of color reproduction, is small and lightweight, and is easy to carry, and does not need to be adjusted for convergence because it is not affected by geomagnetism. Therefore, the projection type color liquid crystal display device is expected to be further developed as an alternative to the projection type CRT display device.

The projection type color image display system using a liquid crystal display device includes a three-plate system using three liquid crystal display devices according to three primary colors and a single plate system using only one liquid crystal display device.

The former three-plate type uses white light for red, green, and blue.
An optical system for splitting each color light into primary colors and three liquid crystal display elements for forming an image by controlling the light intensity of each color light are independently provided, and images of each color are optically overlapped for full color display. Is to do. This three-plate configuration has the advantage that the light emitted from the white light source can be effectively used and the color purity is high, but since the color separation system and the color synthesis system are required as described above, the optical system Is complicated and the number of parts increases, and in terms of cost reduction and miniaturization,
It is generally disadvantageous compared to the single plate type described later.

On the other hand, the latter single-panel type is a structure in which only one liquid crystal display element is used, and a projection optical system projects a liquid crystal display element having a three-primary color filter pattern such as a mosaic shape or a stripe shape. Some of them are disclosed in, for example, JP-A-59-230383. Since the single plate type requires only one liquid crystal display element and the optical system has a simpler structure than the three plate type, it is suitable for a low-cost and small projection system.

However, in the case of the above single plate type,
Only about 1/3 of the incident light can be used because the color filter absorbs or reflects the light. That is, the brightness of the screen in the single plate type using the color filter is about 1/3 of that in the three plate type using the light source of the same brightness.
Will fall to.

In order to solve such a drawback, for example, Japanese Patent Application Laid-Open No. 4-60538 proposes a single plate type color liquid crystal display device which does not use a color filter. In this color liquid crystal display device, as shown in FIG. 13, three dichroic mirrors (hereinafter referred to as DM
54R, 54G, and 54B are used to split the white light from the white light source 51 into red, blue, and green light beams, which are incident on the liquid crystal module with a microlens 50. The liquid crystal module 50 includes a liquid crystal panel 5
7, a microlens array 55 is provided on the light source side. As shown in FIG. 14, the DM 54R / 54G /
The light flux of each color split by 54B is transmitted to the liquid crystal panel 57.
The light enters the microlens array 55 arranged on the light source side at different angles. Each light flux passing through the microlens array 55 has signal electrodes 56R and 56R to which video signals corresponding to respective colors are independently applied.
The liquid crystal part driven by G.56B is distributed and irradiated according to the incident angle of each light beam. As a result, the light flux of each color has its light intensity modulated according to the video signal corresponding to each color, and after passing through the liquid crystal panel 57, as shown in FIG. 13, the field lens 58 and the projection lens 59.
Is projected onto the screen 60 via.

The single plate type color liquid crystal display device which does not use the conventional color filter will be described in more detail including the liquid crystal driving mechanism with reference to FIG.

This color liquid crystal display device includes a liquid crystal module 50 with a microlens and DM54R.54.
The liquid crystal module 5 in which a plurality of light fluxes having different wavelength ranges from G.54B are common from different directions
A light irradiation system for making the light incident on 0 and a liquid crystal module drive circuit 61 for driving the liquid crystal module 50 are provided.

The liquid crystal module 50 includes a liquid crystal panel 5
7, source drivers 63a and 63b connected to the signal electrodes of the liquid crystal panel 57, and a gate driver 64 connected to the gate electrodes (scanning electrodes) of the liquid crystal panel 57.
And the microlens array 55 (see FIG. 13) described above.

The liquid crystal module drive circuit 61 is an NT
From video input signals such as SC signals, R (red), G (green), B
Create the video signals S _R , S _G , S _B for each (blue) liquid crystal,
A liquid crystal video signal generation circuit 65 to be supplied to the liquid crystal module 50, and a timing controller 66 that generates a source drive signal (clock signal, start signal) and a gate drive signal and supplies them to the liquid crystal module 50 are provided.

The liquid crystal video signals S _R , S _G, and S _B from the liquid crystal video signal generation circuit 65 are input to the video signal input terminals R _in , G _in, and B _in of the liquid crystal module 50, respectively, and are source drivers. It is supplied to 63a and 63b. The source drivers 63a and 63b sample the input liquid crystal video signals S _R , S _G, and S _B for each horizontal scanning period based on the source drive signal from the timing controller 66, and sample the liquid crystal video signals S _R S _G · S
_B is a signal electrode at a fixed position (that is, a signal electrode that drives a pixel group corresponding to the incident position of the light flux of each color)
Output to. Then, the liquid crystal video signals S _R , S _G ,
S _B is supplied.

As described above, the light irradiation system and the microlens array 55 allocate the colors to the pixels (the allocation of the incident positions of the light fluxes of the colors to the liquid crystal panel 57) and the source drivers 63a and 63b allocate the pixels. Since the color allocation (the allocation of the liquid crystal video signals S _R , S _G , S _B to be output to each pixel) is matched, the light flux of each color is transmitted through the liquid crystal panel 57, and thus the light flux of each color is transmitted to each color. The light intensity is modulated according to the corresponding liquid crystal video signals S _R , S _G, and S _B.

Since this apparatus does not use an absorption type color filter, the utilization efficiency of light is improved and an extremely bright color image can be provided.

[0015]

In the single-panel type small projection type system using the above-mentioned color filter, the display color of each pixel is fixed by the color filter. Further, even in the single-panel type color liquid crystal display device of the above without using a color filter, a color signal (video signal for a liquid crystal to be supplied to the color and the pixels of the light beam incident on each pixel S _R
・ S _G・ S _B ) are defined, and the display color of each pixel is fixed.

Therefore, in the above-mentioned conventional configuration, if the liquid crystal panel has one or a plurality of green bright spots having high luminous brightness, the display quality is adversely affected, and the defect is judged according to the point defect criterion. However, the bright spot cannot be changed to another color having low luminous brightness.

[0017]

Means for Solving the Problems Claim 1 or Claim 2
The projection type color liquid crystal display device according to the invention of 3) has a plurality of light fluxes having different wavelength bands (for example, R (red) wavelength band, G (green) wavelength band, and B (blue) wavelength band). A light irradiation system that allows different types of light beams to enter a common liquid crystal display element from different directions, and a light condensing unit that condenses each of the above light beams that are incident at different angles to a pixel according to the incident angle. Then, the liquid crystal display element that optically modulates each light beam condensed by the light condensing means and transmitted through each pixel, and each pixel of the liquid crystal display element is driven by a drive signal corresponding to the light beam transmitted through each pixel. In order to solve the above problems, a liquid crystal driving means for driving is provided, after each light beam is optically modulated by the liquid crystal display element, and is displayed in color on the display screen.
Each is characterized by the following measures.

In the projection type color liquid crystal display device according to the first aspect of the present invention, the liquid crystal driving means emits light corresponding to each of the light fluxes according to an incident angle of each of the light fluxes to the liquid crystal display element. Pixel switching means for switching the pixel to be modulated is provided.

In the projection type color liquid crystal display device according to the second aspect of the present invention, the display area of the liquid crystal display element is divided into a plurality of areas, and each of the divided display areas is provided with a plurality of the light irradiation systems. Then, the liquid crystal drive means, for each divided display area, pixel switching means for switching the pixel for performing light modulation corresponding to each light flux in accordance with the incident angle of each light flux to each divided display area. I have it.

[0020]

According to the structures of the first and second aspects of the invention, a plurality of light beams having different wavelength ranges are irradiated to the common liquid crystal display element from different directions, and the light converging means causes the light to be emitted. Each of the light fluxes is condensed on a pixel according to the angle of incidence on the liquid crystal display element. A drive signal corresponding to a light beam passing through each pixel is supplied to each pixel of the liquid crystal display element from the liquid crystal driving means, and each light beam corresponds to each light beam when passing through each pixel of the liquid crystal display element. Light intensity modulation at the pixel,
After that, they are combined on the display screen to form a color image.

For example, the presence of bright spots (for example, green bright spots) having a high luminous brightness in the display area of the above liquid crystal display element has a bad influence on the display quality.

In this case, according to the structure of the first aspect of the invention, the liquid crystal display element of the luminous flux having a wavelength band having a high luminous brightness and the incident angle of the luminous flux having a wavelength band of a lower luminous brightness to the liquid crystal display element. If the incident angle to the light is switched, the pixel switching means of the liquid crystal driving means switches the pixel for performing the light modulation corresponding to each light flux (switches the drive signal supplied to the pixel) correspondingly. It has become. This allows
It is possible to change a bright spot having a high luminous brightness of the liquid crystal display element to a bright spot having a lower luminous brightness (for example, a blue bright spot), thereby improving the display quality.

According to a second aspect of the invention, the display area of the liquid crystal display element is divided into a plurality of areas, and each of the divided display areas is provided with the light irradiation system and the pixel switching means. The same operation as that of the invention of claim 1 can be performed in units of divided display areas.

Therefore, in the display area of the above-mentioned liquid crystal display element, bright spots having high luminous brightness (for example, green bright spots) and bright spots having low luminous brightness (for example, blue bright spots) are respectively formed. In the case of being clustered in another area, in the structure of the invention of claim 2, in the divided display area in which the bright spots having high luminous intensity are unevenly distributed, the luminous flux having the wavelength band having the high luminous intensity and the luminous intensity higher than that. By changing the incident angle to the liquid crystal display element with the light flux having a low wavelength range, and switching the pixels that perform the light modulation corresponding to each light flux, a bright point with low luminous brightness can be obtained from the beginning. It is possible to change a bright spot having high luminous brightness to a bright spot having lower luminous brightness without affecting the existing region, thereby improving the display quality.

[0025]

【Example】

[Embodiment 1] An embodiment of the present invention will be described with reference to FIGS.
The explanation is based on the following.

As shown in FIG. 2, the projection type color liquid crystal display device according to the present embodiment is basically a liquid crystal module with a microlens having a plurality of light fluxes having different wavelength ranges from different directions. Light irradiation system 1 to be incident on 2
A liquid crystal module 2 with a microlens as a liquid crystal display element that forms an optical image by modulating the light intensity of each light flux transmitted at different angles, and a liquid crystal module drive circuit 3 that drives the liquid crystal module 2. The liquid crystal module 2
A projection optical system 4 arranged on the light emission side of the projection optical system for projecting an optical image of each light beam formed by passing through the liquid crystal module 2 onto the screen 5 and producing a combined color image on the screen 5; And a screen 5 as

The light irradiation system 1 includes a white light source 6 such as a halogen lamp or a xenon lamp, a spherical mirror 7 provided on the back surface of the white light source 6, and a condenser lens 8 provided on the front surface of the white light source 6. , Three dichroic mirrors arranged in a fan shape in front of the condenser lens 8 (hereinafter,
It is composed of 9R, 9G, and 9B (abbreviated as DM). The white light source 6, the spherical mirror 7, and the condenser lens 8 are arranged so that the center of the spherical mirror 7 and the focus of the condenser lens 8 are substantially aligned with the center of the light emitting portion of the white light source 6, respectively. The white light emitted from the condenser lens 8 becomes a substantially parallel light beam and is incident on the DM 9R, 9G, and 9B.

The DM9R selectively reflects only light in the R (red) wavelength band and transmits light in other wavelength bands.
The DM9G selectively reflects only light in the G (green) wavelength band and transmits light in other wavelength bands. DM9B is B
Only light in the (blue) wavelength band is selectively reflected, and light in other wavelength bands is transmitted. These DM9R / 9G / 9B
Are arranged in a fan shape on the optical axis of the substantially parallel white light flux emitted from the condenser lens 8. Each DM9R, 9G, 9G
The incident angles of light on B are different from each other. For this reason,
The R, G, and B light fluxes reflected by the DMs 9R, 9G, and 9B enter the display area of the liquid crystal module with microlenses 2 from different directions.

The color liquid crystal display device of the present embodiment is different from the prior art in that the DM9R, 9G and 9B are arranged so that the arrangements thereof can be interchanged with each other, which is a characteristic feature of the present embodiment. There is one. DM9R / 9G / 9
By changing the arrangement of B, it is possible to change the incident angle of the light flux of each color to the liquid crystal module with a microlens 2.

Liquid crystal module with microlens 2
1, a liquid crystal panel 12 forming a display area, a first source driver 13a, a second source driver 13b and a gate driver 14 for driving the liquid crystal panel 12, and a light incident side of the liquid crystal panel 12. And a microlens array 11 (see FIG. 2) provided in the.

Here, an active matrix type liquid crystal panel 12 having a pixel arrangement in a stripe arrangement will be described as an example. In this liquid crystal panel 12, liquid crystal is sealed between a pair of transparent insulating substrates that are arranged to face each other, and pixel electrodes and semiconductor active elements (TFTs, etc.) are formed in a matrix on the inner surface of one substrate. A large number of strip-shaped signal electrodes made of a transparent conductive film for supplying video signals to these,
And a large number of band-shaped gate electrodes for supplying a drive signal to the semiconductor active element are formed so as to be orthogonal to each other, and a counter electrode (common electrode) is formed on the inner surface of the other substrate. . First and second source drivers 13a and 13b are connected to the signal electrodes, and a gate driver 14 is connected to the gate electrodes.

The microlens array 11 focuses the incident light flux of each color on each pixel of the liquid crystal panel 12. The light flux of each color that enters the microlens array 11 at mutually different angles is distributed by the microlens array 11 to different pixels depending on the incident angle. Since the pixel array of the liquid crystal panel 12 is a stripe array, a lenticular lens array in the length direction of the signal electrode (a lens-shaped lens group extending in the length direction of the signal electrode) is used as the microlens array 11. Therefore, light beams of the same color are condensed on each pixel on the same line in the length direction (vertical direction) of the signal electrode. Then, the light flux of each color is sequentially focused on pixels on adjacent lines, and the light flux of the same color is focused at intervals of three lines.

The liquid crystal module drive circuit 3 for driving the liquid crystal module 2 includes a liquid crystal image signal generation circuit 15 and
Timing controller 16 and video signal switching circuit 17
And a video signal switching control circuit 18 and a mirror position detection sensor 19.

The liquid crystal video signal generating circuit 15 converts the NTSC signal, which is a video input signal, into R (red), G (green),
Separate the B (blue) video signals and separate the liquid crystal video signal S _R ·
This is to create S _G S _B. The timing controller 16 creates a source drive signal (clock signal, start signal) and a gate drive signal and supplies them to the liquid crystal module 2.

The mirror position detecting sensor 19 is DM9.
The video signal switching control circuit 18 detects the respective positions of R, 9G, and 9B, and provides the mirror position information according to their positions.
Is output to. This mirror position detection sensor 19
For example, when DM9R, 9G, and 9B are arranged at predetermined positions, a unique identification portion (for example, a hole or a protrusion formed at a different position for each DM) is formed on a part of each DM. A known sensor such as a mechanical switch such as a micro switch or an optical switch including a light emitting element and a light receiving element may be used for detection.

The video signal switching control circuit 18 creates a switching control signal for controlling the signal switching operation of the video signal switching circuit 17 based on the mirror position information and outputs it to the video signal switching circuit 17. is there. The video signal switching circuit 17 switches the liquid crystal video signals S _R , S _G, and S _B output from the video signal output terminals A _out , B _out, and C _out based on the switching control signal, The liquid crystal video signals S _R , S _G , S _B are output to the liquid crystal module 2.

The liquid crystal module 2 has three video signal input terminals A _in , B _in and C _in for inputting liquid crystal video signals S _R , S _G and S _B , and these terminals are Video signal output terminal A of the liquid crystal module drive circuit 3, respectively
_It is connected to _out , B _out, and C _out .

The difference between the liquid crystal module drive circuit 3 and the prior art is that the arrangement of the DM 9R, 9G and 9B is detected by the mirror position detection sensor 19 as described above, and the liquid crystal image signal S is detected according to the detection result. _R・ S _G・
S _B is the video signal input terminal A _in / B _in of the liquid crystal module 2.
-It is a point assigned to C _in . In the example of FIG. 1, the video signal input terminal A _in of the liquid crystal module 2 is an R (red) liquid crystal video signal S _R , the video signal input terminal B _in is a G (green) liquid crystal video signal S _G , Video signal input terminal C _in is B (blue)
The liquid crystal video signal S _B is assigned.

Video signal inputs A, B, C input from the above video signal input terminals A _in , B _in , C _in (A in FIG. 1 is S
_R , B is S _G , and C is S _B ) are supplied to the first and second source drivers 13a and 13b, respectively. The first and second source drivers 13a, 13b sample the video signal inputs A, B, C for each horizontal scanning period based on the source drive signal from the timing controller 16, and sample the video signal inputs A, B, C. B and C are output to the signal electrodes at fixed positions. That is, the first and second source drivers 13a and 13b assign the video signal inputs A, B, and C to the dots at the predetermined positions on the liquid crystal panel 12, respectively. Then, the video signal is supplied to each pixel of the scanning line selected by the gate driver 14.

As a result, in the DM arrangement shown in FIG. 1, "R", "G", and "B" are assigned to each pixel of the liquid crystal panel 12 shown in FIG.
The colors will be sorted as described in the letters
The liquid crystal video signal S _R is supplied to the pixel indicated by “R”, the liquid crystal video signal S _G is supplied to the pixel indicated by “G”, and the liquid crystal video signal S _B is supplied to the pixel indicated by “B”. It

3 by reflecting with the above DM9R, 9G, 9B
The light flux of each color incident on the microlens array 11 from the direction is condensed by the microlens array 11 to the pixels corresponding to the color distribution of the liquid crystal panel 12.
Then, the light flux of each color is transmitted through the liquid crystal panel 12, whereby the liquid crystal video signal S _R ·
The light intensity is modulated according to S _G · S _B.

As shown in FIG. 2, the projection optical system 4 arranged on the light emitting side of the liquid crystal module 2 includes the liquid crystal panel 12 described above.
The field lens 20 that converges the light that has passed through and the projection lens 31. The light fluxes of the respective colors transmitted through the liquid crystal panel 12 and optically modulated are combined on the screen 5 and displayed as a color image.

Next, from the state of FIG. 1, DM9G and DM9B
A case where the positions of and are exchanged will be described with reference to FIG.

In this case, the mirror position detection sensor 19 outputs the mirror position information according to the arrangement of DM9R, 9G and 9B in FIG. 3 to the video signal switching control circuit 18. The video signal switching control circuit 18 outputs a switching control signal according to the mirror position information to the video signal switching circuit 17. The video signal switching circuit 17 outputs from the video signal output terminal A _out to the liquid crystal video signal S _R , from the video signal output terminal B _out to the liquid crystal video signal S _B , from the video signal output terminal C _out in accordance with the switching control signal. The output destination of the liquid crystal video signal of each color is switched so that the liquid crystal video signal S _G is output.

As a result, the video signal input A input to the video signal input terminals A _in , B _in, and C _in of the liquid crystal module 2 is input.
In B and C, R (red) liquid crystal video signal S _R is input to the video signal input A, B (blue) liquid crystal video signal S _B is input to the video signal input _B , and G is input to the video signal input C. The (green) liquid crystal video signal S _G is assigned. As a result, DM shown in FIG.
In this arrangement, “R” is assigned to each pixel of the liquid crystal panel 12 of FIG.
Colors are distributed as shown by the letters "G" and "B", and the liquid crystal video signal S _R is shown in the pixel indicated by "R" and the liquid crystal video signal is shown in the pixel indicated by "G". S _G ,
The liquid crystal video signal S _B is supplied to the pixel indicated by “B”.

As described above, when the arrangement of DM9R, 9G, and 9B is changed, the angle at which the light flux of each color separated from the white light flux by DM9R, 9G, and 9B is incident on the microlens array 11 is changed, and the light flux of each color is changed. Although the allocation to the pixels of is changed, the color distribution of the liquid crystal panel 12 is automatically changed accordingly, that is, the pixels for performing the light modulation corresponding to the light flux of each color are switched, so that the light flux of each color is changed. The light is modulated by the corresponding pixel.

Here, FIG. 4 shows an example of a liquid crystal panel having several bright spots. The circle marks in the figure indicate the positions of the bright spots. A screen display when this liquid crystal panel is used in the state shown in FIG. 1 is shown in FIG. As is clear from FIG. 5, all the bright spots are green bright spots with high luminous brightness,
Very badly affects the display quality. Therefore, if the same liquid crystal panel is used in the state shown in FIG. 3 in which the positions of DM9G and DM9B are switched from the state of FIG. 1, the screen display is as shown in FIG. It turns into a low blue bright spot, and the display quality can be greatly improved as compared with the display state of FIG.

As described above, the projection type color liquid crystal display device according to the present embodiment has R, G, and
Light irradiation system 1 for making three kinds of light fluxes of B incident on a common liquid crystal module with a microlens 2 from mutually different directions
And a microlens array 1 for converging each of the above-mentioned luminous fluxes that are incident at mutually different angles into pixels according to the incident angle
1. A liquid crystal module with a microlens 2 having a microlens array 11 for light-modulating each light flux condensed by the microlens array 11 and transmitted through each pixel, and a light flux transmitting each pixel through each pixel of the liquid crystal module 2. Liquid crystal driving means (the liquid crystal module driving circuit 3, the first and second source drivers 13a and 13b, and the gate driver 14) that are driven by the driving signals (the liquid crystal video signals S _R , S _G, and S _B ) corresponding to After optical modulation of each luminous flux in the liquid crystal module 2,
A pixel for performing color display by synthesizing on the screen 5, wherein the liquid crystal driving means performs light modulation corresponding to each of the light fluxes in accordance with an incident angle of each of the light fluxes to the liquid crystal module 2. And a pixel switching means (a video signal switching circuit 17, a video signal switching control circuit 18, and a mirror position detection sensor 19) for switching between.

As a result, when there is a green bright spot having a high luminous brightness in the display area of the liquid crystal module 2, the display quality is adversely affected, and the defect is judged according to the point defect criterion, but it is judged as green. Corresponding to changing the angle of incidence of the blue luminous flux, by switching the drive signal to the pixel that performs optical modulation corresponding to each luminous flux, the green bright spot becomes a blue bright spot with low luminous brightness. It is possible to change the display quality, improve the display quality, and avoid the defect determination depending on the point defect standard to make the product good.

[Second Embodiment] Next, another embodiment of the present invention will be described below with reference to FIGS. 7 to 12. For convenience of explanation, members having the same functions as the members shown in the above-mentioned embodiment are designated by the same reference numerals, and the description thereof will be omitted.

In the color liquid crystal display device according to this embodiment, as shown in FIG. 7, the display area of the liquid crystal panel 12 is divided into left and right (in the lengthwise direction of the gate electrode) first display area D1. Two light irradiation systems 21 and 22 corresponding to the respective second divided display areas D2 are provided.

Each of the light irradiation systems 21 and 22 described above has its own dedicated DM21R, 21G, 21B or DM22R.
・ Has 22G and 22B, and can change DM arrangement independently. The DM21R and DM22R are
Only light in the R (red) wavelength band is selectively reflected, and light in other wavelength bands is transmitted. DM21G and DM22G
Selectively reflects only light in the G (green) wavelength band and transmits light in other wavelength bands. DM21B and DM2
2B selectively reflects only light in the B (blue) wavelength band,
Light in other wavelength bands is transmitted. Each light irradiation system 21 ・ 22
DM21R ・ 21G ・ 21B and DM22R ・ 22G
22B are arranged in a fan shape on the optical axis of the substantially parallel white light flux, as in the DM of the first embodiment.

Further, the liquid crystal module drive circuit 3 of the present embodiment includes the first mirror position detection sensor 19a for detecting the positions of the DM21R, 21G and 21B of the light irradiation system 21 and the DM22R, 22G and 22B of the light irradiation system 22. And a second mirror position detection sensor 19b for detecting the position of.

[0054] The liquid crystal module drive circuit 3 of this embodiment, the first video signal output terminal 1A _{ou t} · 1B _out · 1C
_out and the second video signal output terminal 2A _out / 2B _out / 2
And a video signal output system of the two systems of the C _{ou t.} Then, the liquid crystal module drive circuit 3 causes the liquid crystal video signal S _R , S _G ,
S _B first video signal output terminal 1A _out , 1B _out , 1C
First video signal switching circuit 1 for switching allocation to _out
7a and a second video signal switching circuit 17b for switching the allocation of the liquid crystal video signals S _R , S _G , S _B to the second video signal output terminals 2A _out , 2B _out , 2C _out . It has a circuit.

The first and second mirror position detecting sensors 1
9a and 19b are DM21R, 21G, and 21B, respectively.
And, the first mirror position information and the second mirror position information according to the arrangement of DM22R, 22G, and 22B are output to the video signal switching control circuit 18 '. The video signal switching control circuit 18 ', based on the first mirror position information and the second mirror position information, the first and second video signal switching circuits 1
The first switching control signal and the second switching control signal for controlling the signal switching operation of 7a and 17b are created, and the first and second switching control signals are generated.
It outputs to each of the video signal switching circuits 17a and 17b.
The first and second video signal switching circuits 17a and 17b are
Liquid crystal images output from the first image signal output terminals 1A _out , 1B _out , 1C _out and the second image signal output terminals 2A _out , 2B _out , 2C _out based on the first and second switching control signals, respectively. The signals S _R , S _G and S _B are switched and output to the liquid crystal module 2.

The liquid crystal module 2 has first video signal input terminals connected to the first video signal output terminals 1A _out , 1B _out , 1C _out and the second video signal output terminals 2A _out , 2B _out , 2C _out. 1A _in / 1B _in / 1C
It is provided with two video signal input systems of _in and the second video signal input terminals 2A _in , 2B _in and 2C _in .

The first video signal input terminals 1A _in and 1B _in
・ Video signal input 1A ・ 1B ・ 1C input from 1C _in
Is supplied to the first source driver 13a, while the video signal inputs 2A, 2B and 2C input from the second video signal input terminals 2A _in , 2B _in and 2C _in are supplied to the second source driver 13b. It

The first source driver 13a samples the video signal inputs 1A, 1B, 1C based on the source drive signal from the timing controller 16 every horizontal scanning period, and the sampled video signal input 1A.
1B and 1C are the first divided display area D of the liquid crystal panel 12.
1 is output to the signal electrode at a fixed position. That is, the first source driver 13a inputs the video signal input 1A to the dots at the predetermined positions in the first divided display area D1 of the liquid crystal panel 12.
1B and 1C are assigned. Further, the second source driver 13b is provided with the video signal inputs 2A, 2B, 2C.
Are sampled for each horizontal scanning period based on the source drive signal from the timing controller 16, and the sampled video signal inputs 2A, 2B and 2C are connected to the liquid crystal panel 1
The signal is output to the signal electrode at the predetermined position in the second divided display area D2. That is, the second source driver 13b assigns the video signal inputs 2A, 2B, and 2C to the dots at the predetermined positions in the second divided display area D2 of the liquid crystal panel 12.

In the DM arrangement shown in FIG. 7, by the first and second video signal switching circuits 17a and 17b, the R (red) liquid crystal video signal S _R and the video are input to the video signal input 1A of the liquid crystal module 2. The B (blue) liquid crystal video signal S _B is allocated to the signal input 1B, the G (green) liquid crystal video signal S _G is allocated to the video signal input 1C, and the video signal input 2A is R (red). Liquid crystal video signal S _R , B (blue) liquid crystal video signal S _{B to} the video signal input 2B, and G (green) liquid crystal video signal S _G to the video signal input 2C.

As a result, in the DM arrangement shown in FIG. 7, "R", "G", "B" are assigned to the respective pixels of the liquid crystal panel 12 shown in FIG.
The colors will be sorted as described in the letters
The liquid crystal video signal S _R is supplied to the pixel indicated by “R”, the liquid crystal video signal S _G is supplied to the pixel indicated by “G”, and the liquid crystal video signal S _B is supplied to the pixel indicated by “B”. It

DM21R, 21G, 21B and D described above
The light flux of each color reflected by the M22R, 22G, and 22B and incident on the microlens array 11 (see FIG. 2) from different directions is directed by the microlens array 11 to the pixels corresponding to the color distribution of the liquid crystal panel 12 described above. Collected. Then, the light flux of each color is transmitted through the liquid crystal panel 12, so that the light intensity is modulated according to the liquid crystal video signals S _R , S _G, and S _B corresponding to the respective colors.

Next, one light irradiation system 21 from the state of FIG.
A case where the positions of the DM 21G and the DM 21B in FIG. 8 are interchanged will be described with reference to FIG.

In this case, the first mirror position detection sensor 19
A change in the positions of the DM 21G and the DM 21B is detected at a, and the first mirror position information according to the arrangement of the DMs 21R, 21G, and 21B in FIG. 8 is output to the video signal switching control circuit 18 '. The video signal switching control circuit 18 'outputs a first switching control signal corresponding to the first mirror position information to the first video signal switching circuit 17a. In response to the first switching control signal, the first video signal switching circuit 17a outputs the liquid crystal video signal S _R from the first video signal output terminal 1A _out and the liquid crystal video signal S _B from the first video signal output terminal 1B _out. , First
The output destination of the liquid crystal video signal of each color is switched so that the liquid crystal video signal S _G is output from the video signal output terminal 1C _out .

Since the DM position of the light irradiation system 22 does not change, the signal switching state of the second video signal switching circuit 17b is the same as in the case of FIG.

As a result, in the video signal inputs 1A, 1B and 1C input to the first video signal input terminals 1A _in , 1B _in and 1C _in of the liquid crystal module 2, the video signal input 1A is R (red). The liquid crystal video signal S _R , the B (blue) liquid crystal video signal S _B is allocated to the video signal input 1B, and the G (green) liquid crystal video signal S _G is allocated to the video signal input 1C. The video signal inputs 2A, 2B and 2C are shown in FIG.
The same liquid crystal video signals S _R , S _G, and S _{B as in the case of} are assigned.

As a result, in the DM arrangement shown in FIG. 8, "R", "G", and "B" are assigned to each pixel of the liquid crystal panel 12 shown in FIG.
The colors will be sorted as described in the letters
The liquid crystal video signal S _R is supplied to the pixel indicated by “R”, the liquid crystal video signal S _G is supplied to the pixel indicated by “G”, and the liquid crystal video signal S _B is supplied to the pixel indicated by “B”. It

As described above, the DM21R of the light irradiation system 21 is used.
When the arrangement of 21G and 21B is changed, the allocation of the light flux of each color to the pixels on the first divided display area D1 by the microlens array 11 changes, but the first divided display area D1 is automatically changed accordingly. The color distribution of the upper pixels is changed, that is, since the pixels that perform light modulation corresponding to the light flux of each color are switched in the first divided display area D1, the light flux of each color is emitted by the pixel corresponding to each color. Is modulated.

Here, FIG. 9 shows an example of a liquid crystal panel having some bright spots. The circle marks in the figure indicate the positions of the bright spots. FIG. 10 shows a screen display when this liquid crystal panel is used in the state shown in FIG. As is apparent from FIG. 10, all the bright spots in the first divided display area D1 are green bright spots having high luminous brightness, which has a very bad influence on the display quality. Therefore, the same liquid crystal panel is changed from the state of FIG.
If it is used in the state shown in FIG. 8 in which the positions of M21G and DM21B are exchanged, the screen display becomes as shown in FIG. 11, and all the bright spots are changed to blue bright spots with low luminous brightness.
The display quality can be greatly improved as compared with the display state of 0.

When the liquid crystal panel shown in FIG. 9 is used in the state shown in FIG. 3 in the first embodiment, the screen display is as shown in FIG. 12, and the second split display area D2 (see FIG. 11). The bright spot in the area corresponding to is a green bright spot with high luminous brightness, which has a very bad effect on the display quality. As can be seen from the above, the color liquid crystal display device of the present embodiment can handle the details more finely than that of the first embodiment.

As described above, the color liquid crystal display device according to this embodiment has three R, G, and B wavelength bands which are different from each other.
The light irradiation systems 21 and 22 that allow different kinds of light beams to enter the common display area of the liquid crystal module 2 from different directions, and the above-described light beams that enter at mutually different angles are condensed into pixels according to the incident angle. A liquid crystal module 2 that has a microlens array 11 that allows the light beams to be modulated by the microlens array 11 and that transmits each light beam that passes through each pixel, and each pixel of the liquid crystal module 2 that transmits each pixel. Drive signal according to luminous flux (LCD video signals S _R , S _G , S _B )
And a liquid crystal driving unit (the liquid crystal module driving circuit 3, the first and second source drivers 13a and 13b, and the gate driver 14) driven by
Each light flux is optically modulated by the above, and is combined on the screen 5 for color display. The liquid crystal module 2 has two display areas (first and second divided display areas D1).
-D2), and the light irradiation system 21 is provided for each divided display area.
22 is provided, and the liquid crystal driving means switches the pixel for performing the light modulation corresponding to each light flux according to the incident angle of each light flux to each divided display area.
Video signal switching circuit 17a, video signal switching control circuit 1
8 ', and the pixel switching means including the first mirror position detection sensor 19a, the second video signal switching circuit 17b, the video signal switching control circuit 18', and the second mirror position detection sensor 1.
The pixel switching means 9b) is provided for each divided display area.

As a result, when green bright spots and blue bright spots exist in separate display areas in the display area of the liquid crystal module 2, in the divided display areas where the green bright spots are unevenly distributed, By switching the incident angles of the green and blue light beams and switching the pixels that perform light modulation corresponding to each light beam, there is no effect on the divided display area in which the bright spots of blue are unevenly distributed, It is possible to change the green bright spot with high luminous brightness to the blue bright spot with lower luminous brightness, improve the display quality, and improperly judge defectiveness depending on the point defect criterion, and make it a good product. Become.

Although the display area is vertically divided into two in this embodiment, the area division is performed by a plurality of vertical divisions, two or more vertical divisions, horizontal divisions or vertical and horizontal divisions depending on the correspondence between the DM and the drive circuit. Examples are possible.

Further, in the above-mentioned first and second embodiments, the pixel arrangement of the liquid crystal panel 12 is a stripe arrangement, but this may be a delta arrangement, and the color arrangement may be a mosaic arrangement or a diagonal RGB arrangement. Absent. Further, regarding the display signal, not only the video signal of the television signal but also an embodiment using a computer or an EWS image signal can be considered.

In the above-described first and second embodiments, an active matrix type liquid crystal panel such as a TFT liquid crystal panel has been described as an example, but the present invention is not limited to this, and for example, a duty liquid crystal panel is used. It may be used and may be any matrix liquid crystal panel.

Each of the above-mentioned embodiments is merely to clarify the technical contents of the present invention, and should not be construed in a narrow sense by limiting to such specific examples.
Various modifications can be made without departing from the spirit of the invention and the scope of the claims.

[0076]

As described above, according to the projection type color liquid crystal display device of the present invention, each of the above-mentioned luminous fluxes is divided into a plurality of luminous fluxes having different wavelength ranges depending on the incident angles to the liquid crystal display element. This is a configuration including a pixel switching unit that switches a pixel for performing corresponding light modulation.

Therefore, when there is a bright spot having a high luminous intensity in the display area of the liquid crystal display element, a liquid crystal having a light beam having a wavelength region having a high luminous intensity and a light beam having a wavelength region having a lower luminous intensity. By changing the incident angle to the display element, the pixel for performing light modulation corresponding to each light flux can be switched correspondingly, so that the bright point having high luminous brightness is changed to the bright point having lower luminous brightness. Therefore, the display quality can be improved.

According to the projection type color liquid crystal display device of the second aspect of the invention, as described above, the display region of the liquid crystal display element is divided into a plurality of regions, and a plurality of light beams having different wavelength regions are directed in different directions. Pixel switching that switches the pixels that perform light modulation corresponding to each light flux according to the incident angle of each light flux to each split display area A means is provided for each divided display area.

Therefore, similar to the effect of the invention of claim 1, the display quality can be improved, and bright spots having high luminous brightness can be displayed in units of divided display areas. Therefore, even if bright spots with high luminous intensity and bright spots with low luminous intensity are present in different areas in the display area of the liquid crystal display element, respectively, A point defect of a liquid crystal display element, such as a bright spot having a high luminous intensity can be changed to a bright spot having a lower luminous intensity without affecting the region where the bright spot having a low luminous intensity exists. The effect that it can respond flexibly according to the state is also exhibited.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention and showing a schematic configuration of a main part of a projection type color liquid crystal display device.

FIG. 2 is a schematic diagram showing an overall configuration of the projection type color liquid crystal display device.

FIG. 3 is a block diagram showing a state of a main part of the projection type color liquid crystal display device when the arrangement of dichroic mirrors is changed from the state of FIG.

FIG. 4 is an explanatory diagram showing an example of a liquid crystal panel having some bright spots.

5 is an explanatory diagram showing a screen display when the liquid crystal panel of FIG. 4 is used in the state of FIG.

6 is an explanatory diagram showing a screen display when the liquid crystal panel of FIG. 4 is used in the state of FIG.

FIG. 7 is a block diagram showing another embodiment of the present invention and showing a schematic configuration of a main part of a projection type color liquid crystal display device.

8 is a block diagram showing a state of a main part of the projection type color liquid crystal display device when the arrangement of dichroic mirrors is changed from the state of FIG.

FIG. 9 is an explanatory diagram showing another example of a liquid crystal panel having some bright spots.

10 is an explanatory diagram showing a screen display when the liquid crystal panel of FIG. 9 is used in the state of FIG. 7.

11 is an explanatory diagram showing a screen display when the liquid crystal panel of FIG. 9 is used in the state of FIG.

12 is an explanatory diagram showing a screen display when the liquid crystal panel of FIG. 9 is used in the state of FIG.

FIG. 13 is a schematic diagram showing an overall configuration of a conventional projection type color liquid crystal display device.

FIG. 14 is a detailed view of a main part of a liquid crystal display element of the conventional projection type color liquid crystal display device.

FIG. 15 is a block diagram showing a schematic configuration of a main part of the conventional projection type color liquid crystal display device.

[Explanation of symbols]

1 Light Irradiation System 2 Liquid Crystal Module with Microlens (Liquid Crystal Display Element) 3 Liquid Crystal Module Driving Circuit (Liquid Crystal Driving Means) 4 Projection Optical System 5 Screen (Display Screen) 6 White Light Source 9R Dichroic Mirror 9G Dichroic Mirror 9B Dichroic Mirror 11 Microlens Array 12 Liquid crystal panel 13a First source driver (liquid crystal driving means) 13b Second source driver (liquid crystal driving means) 14 Gate driver (liquid crystal driving means) 15 Liquid crystal video signal creation circuit 16 Timing controller 17 Video signal switching circuit (pixel switching) Means) 17a First video signal switching circuit (pixel switching means) 17b Second video signal switching circuit (pixel switching means) 18 Video signal switching control circuit (pixel switching means) 18 'Video signal switching control circuit (pixel switching means) 19 Mirror position detection Output sensor 19a First mirror position detection sensor 19b Second mirror position detection sensor 21 Light irradiation system 21R Dichroic mirror 21G Dichroic mirror 21B Dichroic mirror 22 Light irradiation system 22R Dichroic mirror 22G Dichroic mirror 22B Dichroic mirror

Claims (2)

[Claims] 1. A light irradiation system in which a plurality of light beams having different wavelength ranges are made incident on a common liquid crystal display element from mutually different directions, and each of the above-mentioned light beams incident at mutually different angles is changed in accordance with an incident angle. A liquid crystal display element that has a light condensing unit that condenses the light on each pixel, and that optically modulates each light beam that is condensed by the light condensing unit and that passes through each pixel; A liquid crystal drive unit for driving with a drive signal according to a light beam that passes through the optical system, wherein each light beam is optically modulated by the liquid crystal display element, and then combined on the display screen for color display. In the above liquid crystal driving means, the liquid crystal driving means is provided with a pixel switching means for switching a pixel for performing light modulation corresponding to each of the light fluxes according to an incident angle of each of the light fluxes to the liquid crystal display element. Projection type color LCD display apparatus. 2. A light irradiation system in which a plurality of light beams having different wavelength ranges are made incident on a common liquid crystal display element from mutually different directions, and each of the above-mentioned light beams which are made incident at different angles depending on the incident angle. A liquid crystal display element that has a light condensing unit that condenses the light on each pixel, and that optically modulates each light beam that is condensed by the light condensing unit and that passes through each pixel; A liquid crystal drive unit for driving with a drive signal according to a light beam that passes through the optical system, wherein each light beam is optically modulated by the liquid crystal display element, and then combined on the display screen for color display. In, the display area of the liquid crystal display element is divided into a plurality of areas,
A plurality of the light irradiation systems described above are provided for each divided display area, and the liquid crystal driving means switches the pixel for performing light modulation corresponding to each light flux according to the incident angle of each light flux to the divided display area. A projection-type color liquid crystal display device comprising a pixel switching means for each divided display area.