JP2890402B2 - Projection color display - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a configuration of a liquid crystal panel in a projection type color display device. [Prior art] A conventional projection type color display device arranges three CRT projection tubes, which respectively display red, green and blue images, which are three primary colors of additive color mixing, and projects them on a screen to combine the three primary color images. It is known to obtain a color image. [Problems to be Solved by the Invention] However, the above-mentioned conventional technology has a problem that a large-sized CRT projection tube is required to obtain a bright color image, so that the apparatus becomes large. In addition, since images projected from three CRT projection tubes are combined on a screen, adjustment is troublesome, and there is a problem that color unevenness occurs at a peripheral portion of the image. The present invention has been made in order to solve such problems and to provide better image display. The purpose of the present invention is to provide a transmission type liquid crystal panel using an active matrix system in which transistors are integrated on a substrate by a light valve. To provide a better display by reducing the size of the projection type color display device and eliminating the performance deterioration due to the influence of light of the transistor integrated on the substrate. [Means for Solving the Problems] The projection type color display device of the present invention comprises: a plurality of transmissive liquid crystal panels each modulating a plurality of color lights based on a data signal; and a color light modulated by each of the transmissive liquid crystal panels. And a projection optical unit for projecting the combined light combined by the color combining unit. The plurality of transmissive liquid crystal panels are configured such that the image of the color light generated by the modulation is horizontally inverted. A first type transmissive liquid crystal panel that modulates the color light guided to the projection optical unit in a state, and a second type that modulates the color light guided to the projection optical unit in a state where the color light image generated by the modulation is not horizontally inverted.
And a transmissive liquid crystal panel of the type, wherein each of the transmissive liquid crystal panels has a liquid crystal sandwiched between a pair of substrates, and the data signal is supplied to one of the substrates. A plurality of signal lines, a plurality of gate lines intersecting the plurality of signal lines, a plurality of transistors connected to the signal lines and the gate lines, and a plurality of pixel electrodes connected to the plurality of transistors. A row-side drive circuit for driving the gate line and a column-side drive circuit for supplying the data signal to the signal line are formed on the other substrate from the local substrate side. A light-shielding layer for shielding the plurality of transistors from incident light is formed, and the first type transmissive liquid crystal panel and the second type transmissive liquid crystal panel are provided by the column side driving circuit. The supply order of the supplied data signals is reversed. Further, the first type transmissive liquid crystal panel and the second type
The transmissive liquid crystal panel of the type is characterized in that the mask pattern is formed by using a left-right inverted mask pattern or only the column-side driving circuit using a left-right inverted mask pattern. [Operation] According to the above configuration of the present invention, if the transmission type liquid crystal panel of the first type and the transmission type liquid crystal panel of the second type are combined,
Only one type of transmissive liquid crystal panel needs to display horizontally inverted. In order to realize this, only one type of transmissive liquid crystal panel may be used upside down, but the light incident surface is reversed and the transistor cannot be sufficiently shielded. Therefore, by configuring a column-side drive circuit so that only one type of transmissive liquid crystal panel can supply a data signal whose right and left are inverted to the pixel electrode, the light incident surface of each transmissive liquid crystal panel is on the same side. Thus, a decrease in performance due to light incident on the transistor can be prevented, and a favorable display can be obtained. Embodiments Hereinafter, embodiments according to the present invention will be described with reference to the drawings. FIG. 1 is a perspective view showing a positional relationship of an optical system using a cube prism, and FIG. 2 is a top view showing a positional relationship of an optical system using a cube prism. In the figure, a projection lens (10) enlarges and displays an image displayed on a liquid crystal panel on a screen. The cube prism (11) is formed by bonding four dichroic layers that reflect light of a specific wavelength on the inclined surface of a right-angle prism, and the blue reflective surface (12) is a blue display liquid crystal panel (16). The transmitted blue light (19) is reflected toward the projection lens (10), and the red reflective surface (13) reflects the red light (17) transmitted through the red display liquid crystal panel (14) toward the projection lens (10). I do. The green ray (18) transmitted through the green display liquid crystal panel (15) passes through the cube prism (11) and reaches the projection lens (10). Here, by adjusting the optical positional relationship of the three liquid crystal panels viewed from the projection lens side, the images displayed on the three liquid crystal panels are combined as one color image, and one projection lens (10) Is projected on the screen, so that a display without color shift can be obtained even in the peripheral portion of the video. The display direction of the image displayed on the screen is usually displayed from left to right and from top to bottom. In order to obtain such a display on the screen, the display direction on the liquid crystal panel must be in the direction indicated by the arrow in the figure. That is, the top and bottom and left and right of the image are inverted by the projection lens (10), and the images on the red display liquid crystal panel (14) and the blue display liquid crystal panel (16) are
The left and right sides are reversed because they are reflected by the cube prism (11). Therefore, the upper and lower display directions of the three liquid crystal panels are displayed from bottom to top, and the left and right display directions of each liquid crystal panel viewed from the light incident side are red display liquid crystal panel (14) and blue display liquid crystal panel ( 16) displays from right to left, and the green LCD panel (15) displays from left to right. This situation will be described with reference to a perspective view showing the display of the liquid crystal panel of FIG. 3. The display of the liquid crystal panel in which liquid crystal is sealed in a gap between the glass substrate (30) and the quartz glass substrate (31) is a glass substrate. When viewed from the (30) side, the image on the red display liquid crystal panel (14) and the image on the blue display liquid crystal panel (16) have a forward rotation with respect to the image on the screen, and the image on the green display liquid crystal panel (15) Are in a reversed relationship. In order to obtain a display such as a green display liquid crystal panel (15), for example, the display can be obtained by turning over the red display liquid crystal panel (14). In this case, a glass substrate (30) and a quartz glass substrate (3
1) is replaced, and the performance of the thin film transistor is reduced. That is, with reference to the partial sectional view of the liquid crystal panel shown in FIG. 4, the pixel portion of the liquid crystal panel has a liquid crystal (65) sealed between a glass substrate (30) and a quartz glass substrate (31). A thin film transistor (62) is formed at (31), and a gate line (60) is connected to its gate electrode, a source (61) is connected to its source electrode, and a pixel electrode (63) is connected to its drain electrode. ing. A common electrode (64) and a light shielding layer (66) for shielding light are formed on the glass substrate (30), and a portion other than the light shielding layer becomes an opening (67). Upper polarizing plate (68)
The lower polarizing plate (69) has a property of transmitting only light of a specific polarization component. When a voltage is applied to a certain gate line (60), the thin film transistor (62) connected to the gate line becomes conductive, and the voltage applied to the source line (61) is applied to the pixel electrode (63) and the common electrode. (64) and charge the capacity composed of
It drives the liquid crystal. However, when light irradiates the thin film transistor (62), the characteristics of the thin film transistor (62) are changed by the light, and the operation becomes poor. Therefore, a light-shielding layer (66) is formed on a glass substrate (30) to form a thin film transistor (6).
2) light is not irradiated. Thereby, even if light is irradiated from the glass substrate (30) side, the performance of the thin film transistor (62) does not decrease. Therefore, the red display liquid crystal panel (14) cannot be turned over and used as a green display liquid crystal panel (15). That is, the drive driver circuit must be configured so that only the green display liquid crystal panel (15) performs display with the left and right inverted. FIG. 5 is a plan view of a liquid crystal panel using an external driver circuit shown as a reference example. A column substrate (41) made of polyimide on which a column driver IC (40) is mounted is arranged above and below the liquid crystal panel. Driving the source line (61) and row driver
A row substrate (43) on which an IC (42) is mounted is arranged on the left and right sides of the liquid crystal panel to drive a gate line (60). The left and right display directions of the red display liquid crystal panel (14) and the blue display liquid crystal panel (16) are as shown by arrows (44), and the column side substrates (41) arranged above and below the liquid crystal panel are turned upside down and the source lines ( If connected to 61), the display will be in the direction indicated by the arrow (45), and a green display liquid crystal panel (15) can be obtained. FIG. 6 is a perspective view of a liquid crystal panel using a built-in driver according to the present invention, and shows only a quartz glass substrate (31). A pixel portion (50) on which a thin film transistor (62) is integrated is formed on a quartz glass substrate (31), and a column side drive signal (52) is formed.
And a circuit for controlling the sample and hold transistor (56) by the operating column driver circuit (51) to write the data of the data signal (55) to the source line (61) and a row side drive signal (54). The row driver circuit (53) for driving the gate line (60) is formed by a thin film transistor. Circuits formed on the quartz glass substrate (31) are formed by mask pattern formation, etching, heat treatment, etc., like semiconductor integrated circuits. It can be easily obtained by using an inverted mask pattern or using a mask pattern in which only the column driver circuit (51) is inverted left and right. [Another Embodiment 1] Fig. 7 is a plan view of an optical system in which dichroic mirrors are combined in an X-shape. One red reflecting dichroic mirror (7) in which a dichroic layer is formed on a thin glass plate.
0) and two blue reflecting dichroic mirrors (71) are combined in a cross shape to perform image synthesis. Red light ray (17) transmitted through the red display liquid crystal panel (14)
Is reflected by the red reflective dichroic mirror (71), and the blue light beam (19) transmitted through the blue display liquid crystal panel (16) is reflected by the blue reflective dichroic mirror (71) to reach the projection lens (10). The green light (18) transmitted through the green display liquid crystal panel (15) is a red reflective dichroic mirror (70)
Then, the light passes through the blue reflection dichroic mirror (71) and reaches the projection lens (10), where the images displayed on the three liquid crystal panels are combined. Also in this case, only the image displayed on the green display liquid crystal panel (15) is opposite to the display direction of the image on the red display liquid crystal panel (14) and the blue display liquid crystal panel (16). [Another Embodiment 2] Fig. 8 is a plan view of an optical system using three dichroic mirrors, and an image on a red display liquid crystal panel (14) is displayed twice on a red reflective dichroic mirror (70) (71). Reflected to the projection lens (10), green display LCD panel (15)
Is reflected by the green reflecting dichroic mirror (72), passes through the red reflecting dichroic mirror (71), and reaches the projection lens (10). The image on the blue display liquid crystal panel (16) passes through the green reflective dichroic mirror (72) and the red reflective dichroic mirror (71) and passes through the projection lens (1).
0). Even in such a case, the left-right direction of the display on the liquid crystal panel is different depending on whether the number of reflections until the image on the liquid crystal panel reaches the projection lens (10) is 0 or even and odd. That is, in this case, the display directions of the red display liquid crystal panel (14) and the green display liquid crystal panel (16) are from right to left when viewed from the light incident side, but only the display direction is left on the green display liquid crystal panel (15). It is necessary to configure the drive driver circuit so as to be displayed on the right side from. The green reflecting dichroic mirror (73) and the two blue reflecting dichroic mirrors (74) separate the white light (75) into three primary colors, red light, green light and blue light. [Effects of the Invention] As described above, according to the present invention, a first-type transmissive liquid crystal panel that modulates color light guided to projection optical means in a state where an image of color light generated by modulation is horizontally inverted is provided. A second type of transmissive liquid crystal panel that modulates the color light guided to the projection optical means in a state where the image of the color light generated by the modulation is not inverted right and left, and each transmissive liquid crystal panel has a liquid crystal between a pair of substrates. A plurality of signal lines to which data signals are supplied, a plurality of gate lines crossing the plurality of signal lines, and a plurality of transistors connected to the signal lines and the gate lines. A plurality of pixel electrodes connected to the plurality of transistors, a row-side drive circuit for driving a gate line, and a column-side drive circuit for supplying a data signal to a signal line are formed. Above,
A light-shielding layer for shielding a plurality of transistors from light incident from the local substrate side is formed. The first type transmissive liquid crystal panel and the second type transmissive liquid crystal panel are provided with a column-side driving circuit. , The supply order of the data signals supplied is reversed, and the following remarkable effects can be obtained. a) The supply of the data signal by the driving circuit of one of the first and second types of transmissive liquid crystal panels is in the opposite direction to the driving circuit of the other type of transmissive liquid crystal panel. Thus, since the image on one panel is horizontally inverted with respect to the other panel, it is not necessary to turn one type of liquid crystal panel over the other liquid crystal panel. Thus, any of the transmissive liquid crystal panels can be arranged so that the color light is incident from the other substrate on which the light shielding layer is formed. Therefore, the light-blocking layer formed on the other substrate can surely shield the transistor formed on one substrate from light, and light leakage of the transistor can be reduced. As a result, the operation of the transistor is stabilized, and the quality of an image formed by modulation in the transmissive liquid crystal panel and thus the quality of the synthesized image can be improved. b) Since not only a pixel portion but also a row-side drive circuit and a column-side drive circuit for driving the pixel portion are formed on a plurality of transmissive liquid crystal panel substrates, the row side drive circuit in each transmissive liquid crystal panel is formed. The need for externally mounting the drive circuit and the column side drive circuit on the liquid crystal panel substrate is eliminated. Therefore, in a projection type color display device having a plurality of transmission type liquid crystal panels, the number of external components to the liquid crystal panel can be reduced and the number of mounting steps can be reduced. Can be c) Assuming that the supply direction to the signal lines of the column-side drive circuits of the first type and second type liquid crystal panels is the same, the supply order of the data signals to the liquid crystal panel outside the liquid crystal panel is changed to the first type and the second type. However, in the present invention, there is no need to change the supply of external data signals to the liquid crystal panel between the first type and the second type of liquid crystal panel, and no extra control is required.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view showing a positional relationship of an optical system using a cube prism. FIG. 2 is a top view showing a positional relationship of an optical system using a cube prism. FIG. 3 is a perspective view showing a display on a liquid crystal panel. FIG. 4 is a partial sectional view of a liquid crystal panel. FIG. 5 is a front view of a liquid crystal panel using an external driver circuit. FIG. 6 is a perspective view of a liquid crystal panel by a built-in driver. FIG. 7 is a plan view of an optical system in which dichroic mirrors are combined in an X-shape. FIG. 8 is a plan view of an optical system using three dichroic mirrors. 10: Projection lens 11: Cube prism 12: Blue reflective surface 13: Red reflective surface 14: Red display liquid crystal panel 15: Green display liquid crystal panel 16: Blue display liquid crystal panel 17: Red light ray 18: Green light ray 19: Blue light ray

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁶ , DB name) G09G 3/36 G02F 1/133 G02F 1/13

Claims (1)

(57) [Claims] A plurality of transmissive liquid crystal panels respectively modulating a plurality of color lights based on data signals; a color synthesizing means for synthesizing the color lights modulated by the respective transmissive liquid crystal panels; and projecting the synthetic light synthesized by the color synthesizing means. A plurality of transmissive liquid crystal panels, wherein the plurality of transmissive liquid crystal panels are of a first type of transmissive liquid crystal that modulates color light guided to the projection optical means in a state where an image of color light generated by modulation is horizontally inverted. A second panel for modulating the color light guided to the projection optical unit in a state where the image of the color light generated by the modulation is not horizontally inverted.
And a transmissive liquid crystal panel of the type, wherein each of the transmissive liquid crystal panels has a liquid crystal sandwiched between a pair of substrates, and the data signal is supplied to one of the substrates. A plurality of signal lines, a plurality of gate lines intersecting the plurality of signal lines, a plurality of transistors connected to the signal lines and the gate lines, and a plurality of pixel electrodes connected to the plurality of transistors. A row-side driving circuit for driving the gate line and a column-side driving circuit for supplying the data signal to the signal line are formed on the other substrate, from the other substrate side. A light-shielding layer for shielding the plurality of transistors from incident light is formed, and the first type transmissive liquid crystal panel and the second type transmissive liquid crystal panel are provided by the column side driving circuit. The projection type color display device, wherein the supply order of the supplied data signals is reversed. 2. The first type transmissive liquid crystal panel and the second type transmissive liquid crystal panel are formed by using a mask pattern obtained by inverting left and right or a mask pattern obtained by inverting only the column side driving circuit. The projection type color display device according to claim 1.