JPH055902A - Liquid crystal display panel - Google Patents

Abstract

PURPOSE:To turn on/off the display electrode of a defective picture element regardless of its defect by arranging a means, which connects display electrodes of adjacent picture elements arranged in the row (or column) direction, across a drain line. CONSTITUTION:A connecting means 40 which connects display electrodes 11 of adjacent picture elements 30 arranged in the row (or column) direction of plural picture elements 30 arranged in a matrix is provided across a drain line 14 between picture elements 30. Therefore, display electrodes 11 of adjacently arranged picture elements 30 are connected by the connecting means 40 even in the case of a conduction defect of an TFT(thin film transistor) 20 which drives one picture element 30. That is, the signal voltage supplied to another picture element 30 adjacent to the defective picture element 30 is supplied to the display electrode 11 of the defective picture element 30, for which the TFT 20 is defective, through the display electrode 11. Consequently, the defective picture element 30 cannot be completely reproduced but can be driven in the same color as the adjacent picture element 30 based on the signal applied to the adjacent display picture element 30.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display panel, and more particularly to a liquid crystal display panel having a TFT.

[0002]

2. Description of the Related Art In recent years, liquid crystal projectors have become available with the increase in screen display. In such a projector, when white light generated from a light source is incident on a dichroic prism via a condenser lens, it is divided into red, green, and blue, and a part of each color component, for example, red and blue, is reflected by a total reflection mirror. After that, the red, green, and blue components, which are respectively modulated by the liquid crystal display panel as a change in transmittance, are further combined by a dichroic mirror and projected on a screen by a projection lens.

As a liquid crystal projector using a liquid crystal display panel, there is Japanese Patent Laid-Open No. 61-150487, and its description is omitted here. In the liquid crystal projector described above, it is necessary to increase the number of pixels of each liquid crystal display panel in order to realize high image quality. For example, if a panel of 480 vertical by 720 horizontal is used, NTSC full line display can be performed. .. However, as the number of pixels increases, TF
T (thin film transistor) has also increased, and there has been a problem that the yield of display panels is reduced.

In order to solve such a problem, a method is generally adopted in which, for example, two TFT elements are formed on one pixel electrode and the TFT element is operated even if any one of them becomes defective.

[0005]

However, even if two TFT elements are provided on one pixel electrode as described above, for example, pinholes are formed by dust or the like during the gate insulating film forming step, In some cases, two TFT elements may be simultaneously defective due to a defective display due to a short circuit between the auxiliary capacitance metal and the pixel electrode, or a defective contact between the semiconductor layer and the source and drain electrodes, or the like.

In this case, since the liquid crystal display panel for the projector is displayed in the normally white mode, the pixel electrode in which the TFT element is defective is displayed as a white dot on the screen. There was a problem of degrading the display quality. Further, if such a TFT element defect occurs at a plurality of places, it cannot be used as a liquid crystal display panel for a projector, and there is a problem that the yield of finished products is significantly reduced.

Further, such a problem may frequently occur with an increase in the number of pixels, which has been a major obstacle to realizing a large-sized display panel.

[0008]

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and displays adjacent pixels arranged in the row (or column) direction of a plurality of pixels arranged in a matrix. The above-described problem is solved by providing a connecting means capable of connecting electrodes between pixels adjacent in the row direction.

[0009]

As described above, according to the present invention, rows (or columns) are
By providing the connecting means for connecting the display electrodes of the adjacent pixels arranged in the horizontal direction between the adjacent pixels in the row (or column) direction, even if all the TFTs driving one pixel become defective in conduction. It is possible to connect the display electrodes of the pixels arranged adjacent to each other by means to display the signal voltage supplied to the other pixel adjacent to the defective pixel through the display electrode of the defective pixel in which the TFT is defective. Although the defective pixel can be supplied to the electrode and the defective pixel cannot be completely reproduced, the defective pixel can be driven in the same color as the adjacent pixel based on the signal applied to the adjacent display pixel.

[0010]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The structure of the present invention will be described below with reference to FIGS. Note that FIG. 2 is a sectional view substantially corresponding to the line AA in FIG. Looking at FIG. 2, first there is a transparent insulating substrate (1). The substrate (1) is made of glass, for example.

On this glass substrate (1), a gate (2), a gate line (3) integrated with the gate, an auxiliary capacitance electrode (4) and an auxiliary capacitance line (5) integrated with the auxiliary capacitance electrode (4). Is provided. Here, the auxiliary capacitance electrode (4) in FIG. 2 indicates the lower right end portion of the letter H in FIG.
Although these (2), (3), (4), and (5) are made of Cr in this embodiment, for example, Ta, TaMo,
Cr-Cu (containing a small amount of Fe) or the like is considered.

As shown in FIG. 1, the gate (2) and the gate line (3) extend in the lateral direction with respect to the plane of the drawing, and although not shown, only the TFT formation region is formed slightly wider. On the other hand, the auxiliary capacitance electrode (4) is formed in an H shape with a dotted line, and an auxiliary capacitance line (5) is provided to connect the auxiliary capacitance electrodes (4) provided adjacent to each other on the left and right. There is.

Although not shown in the drawing, a gate terminal and an auxiliary capacitance terminal are provided around the glass substrate (1), and the final structure of each is a gate line (3) and an auxiliary capacitance line. (5) is connected.
Next, there is a gate insulating film (7) covering the gate (2), the gate line (3), the auxiliary capacitance electrode (4) and the auxiliary capacitance line (5). This film is a SiNx film formed by the plasma CVD method. Here, S is used instead of the SiNx film.
An iO ₂ film may be used, or these two films may be laminated. When the SiNx film or the SiO ₂ film is used alone, the film forming process may be divided into two steps to have a two-layer structure.

Next, an amorphous silicon active layer (a-S) is formed on the gate insulating film (7) corresponding to the TFT.
i layer) (8) and amorphous silicon contact layer (N ⁺ a-Si layer) (9) are laminated to form an a-Si layer (8) and an N ⁺ a-Si layer (9) corresponding to the channel. A semiconductor protective film (10) made of a SiNx film is provided between them. This semiconductor protective film (10) is N ⁺ a-
When etching the Si layer (9), the a-Si layer (8)
Of the gate insulating film (7),
By continuously forming the a-Si layer (8) and the SiNx film (10), it has a function of improving the switching characteristics of the TFT.

Referring to FIG. 2, the a-Si layer (8) is provided in a quadrangle shown by a dotted line and a solid line, which is slightly wider than the gate (2) constituting the TFT. Further, the semiconductor protective film (10) is provided in the center of the gate (2) in a quadrangle shown by a solid line. Furthermore, an N ⁺ a-Si layer (9)
Are provided in the hatched area. On the other hand, the display electrode (11) is made of ITO which is a transparent electrode and is connected to a source electrode (12) described later.

Further, N ^{+ a-} corresponding to the source of the TFT
The source electrode (12) extending from the Si layer (9) to the display electrode (11) and N ⁺ a-S corresponding to the drain of the TFT
A drain line (14) integral with the drain electrode (13) extending from the i-layer (9) to the drain terminal is provided. Although the electrodes (12), (13) and (14) are made of Al-Mo in this embodiment, they may be made of other metals. With this structure, the display electrode (11) and the TFT element (20) are formed in the region (30) of one pixel unit divided by the drain line (14) and the gate line (3).

A feature of the present invention is that the connecting means (40) is capable of displaying the display electrodes (11) of other pixels (30) arranged adjacent to each other in the row (or column) direction.
Are provided over pixels (30) adjacent to each other in the row (or column) direction. That is, when the TFT element (20) for driving the display electrode (11) becomes defective, the connection means (40) outputs a drive signal for driving the display electrodes (11) adjacently arranged in the row (or column) direction. The display electrode (11) connected to the defective TFT via the display electrode (11) of the normal pixel is simultaneously turned on / off.

The connecting means (40) is provided with the display electrodes (11) of the pixels (30) arranged adjacent to each other in the row (or column) direction.
Are provided so that they can be connected. Therefore, in this embodiment, as shown in FIG. 1, the drain line (1) extending between the pixels (30) adjacent to each other in the row direction.
It is provided so as to straddle 4). FIG. 3 shows B- of FIG.
It is a B sectional view, and the connecting means (40) is composed of a metal film (33) and connecting electrodes (31A) (31B). The metal film (33) is formed of the same material and in the same process as the gate electrode and the gate line, and its peripheral edge portion is overlapped with the display electrodes (11) of the adjacent pixels (30) arranged in the row direction. Connection electrodes (31A) and (31B) are provided on the upper layer on which the display electrodes (11) and (11) are overlapped with the metal film (33) through an insulating film (32). The connection electrodes (31A) (31B) are formed simultaneously when the drain line (14) is formed.

After forming a plurality of pixels and the above-mentioned connecting means (40) on the substrate (1), an alignment film made of, for example, polyimide is provided on the upper layer (not shown). On the other hand, a counter glass substrate that is paired with the glass substrate (1) is provided, and a light shielding film is provided at a position corresponding to the TFT on the counter glass substrate, and a counter electrode is provided.
Further, the above-mentioned alignment film is provided.

Further, a spacer is provided between the pair of glass substrates, the periphery is sealed with a sealing material, and liquid crystal is injected through the injection hole to obtain a liquid crystal display panel. The display panel is subjected to a predetermined inspection to check whether each TFT element (20) has a malfunction. For example, when various video signals are input to the TFT element (20) using a device such as a pattern generator, if the TFT element (20) malfunctions, the display electrode (11) will have white dots (or black dots). And inform the observer.

In the liquid crystal display panel structure of the present invention, as described above, even if the TFT element (20) becomes defective and the display electrode (11) of the defective pixel cannot be displayed, the pixel (30) arranged adjacent in the row direction is used. ), The display electrode (11) of the pixel (30) for which the signal voltage supplied to the () is normal, and the connecting means (4)
Display electrode (1) of a defective pixel which cannot be displayed through
Since 1) can be turned on / off at the same time as the display electrodes (11) of the normal pixels adjacently arranged, it is possible to balance the surrounding contrast.

That is, polarizing plates are arranged above and below the display panel, and a black (or white) level signal is input to the panel from the pattern generator. Then, the pixel having the defective TFT element displays a white (or black) dot. Then YA
A display panel is placed on the stage of a microscope in which a G laser or the like is set, and transmitted light is emitted from the counter substrate side, for example.
Place the white (or black) point in the field of view of the microscope. Furthermore, the display electrode (11) of the pixel adjacent to the display electrode (11) of the pixel in which the display electrode (11) is white (or black)
It is possible to drive the display electrode (11) of the defective pixel at the same time as the normal pixel adjacently arranged by connecting and using the connection means (40). That is, as shown in FIG. 4, the connecting electrodes (31A) (31B) and the display electrodes (11) are formed by using laser light.
When the laser light is irradiated for a predetermined time on the portion where (11) and the metal film (33) overlap each other, the connecting electrodes (31A) (31)
A display in which a hole (35) is formed in the insulating film (32) as B) melts, and a part of the melted metal flows into the wall surface of the hole (35) and is adjacently arranged through the metal film (33). The electrodes (11) and (11) are connected to each other. As a result,
Even if all the TFTs that drive one pixel are defective in conduction, the signal voltage supplied to other pixels adjacent to each other by the connecting means provided between pixels arranged in the row direction causes the TFT to become defective. It becomes possible to supply to the display electrode of the defective pixel. In the above-described embodiments, the display panel for the liquid crystal projector has been described, but the present invention is not limited to the projector panel, and can be used for a large OA display panel or a TV display panel. Not to mention.

[0023]

As described above in detail, according to the present invention,
Although the defective pixel cannot be completely reproduced, the signal applied to the adjacent display pixel can be supplied to the display electrode of the defective pixel through the connecting means provided between the pixels adjacent in the row direction. Therefore, the defective pixel can be driven to the same color as the adjacent pixel. As a result, it is particularly effective when defective pixels occur in the liquid crystal display panel for a projector used in the normally white mode.

[Brief description of drawings]

FIG. 1 is a plan view of a liquid crystal display panel of the present invention.

FIG. 2 is a sectional view taken along line AA of FIG.

FIG. 3 is a sectional view taken along line BB of FIG.

FIG. 4 is a cross-sectional view after correction.

[Explanation of symbols]

 (1) Glass substrate (2) Gate electrode (3) Gate line (4) Auxiliary capacitance electrode (20) TFT element (30) Pixel region (40) Connecting means

Claims (1)

Claim: What is claimed is: 1. A liquid crystal display panel comprising: a matrix of pixels, each of which is composed of at least one TFT (thin film transistor) connected to a display electrode on a substrate.
A liquid crystal display panel, characterized in that connecting means for connecting display electrodes of adjacent pixels arranged in a row (or column) direction is arranged across a drain line. 2. The connection means is arranged such that one end thereof is superposed on a display electrode of one pixel and the other end thereof is superposed on a display electrode of an adjacent pixel. The liquid crystal display panel described.