JPH02179616A - Liquid crystal display device - Google Patents

Abstract

PURPOSE:To reduce the occurrence of display defects and to increase the screen size by providing a display driving means which individually drives divided display areas for display and a divided display area connection preparing means which can connect digital display areas in each picture element display area to each other after the fact. CONSTITUTION:A first divided picture element electrode 14 is provided with a TFT 16, and a second divided picture element electrode 18 is provided with a TFT 20, and an integrated picture element electrode 30 electrically connected to both divided picture element electrodes 14 and 18 is provided. When a leak defect occurs in the TFT 16, the divided picture element electrode 14 is disconnected from the TFT 16 by a cut part 44 with a laser or the like. At this time, a voltage is not applied to the divided picture element electrode 14 by the TFT 16 but a prescribed voltage is applied to the divided picture element electrode 18 through the TFT 20, and as the result a prescribed voltage is applied to the integrated picture element electrode 30, and the picture element is normally operated. Since the integrated picture element electrode 30 can be formed to cover the whole of the picture element, it is unnecessary to form a black stripe between divided picture element electrodes and the aperture rate is raised.

Description

[Detailed description of the invention]

[Industrial Field of Application] The present invention relates to an active matrix liquid crystal display device, and more particularly to an active matrix liquid crystal display device in which a plurality of switching elements are provided on a picture element electrode constituting one picture element. [Prior Art] An active matrix drive method is adopted as a liquid crystal display device. In this driving method, each pixel of a liquid crystal device is provided with a switch element and, if necessary, a signal storage element, and the liquid crystal is driven by an integrated configuration. Figure 7 shows an insulated gate thin film transistor (hereinafter referred to as TPT).
FIG. 3 is a diagram illustrating the operating principle of an active matrix liquid crystal display device in which a switch element (abbreviated as ``1'') is used as a switch element and a signal storage element is provided. Referring to FIG. 7, the active matrix display device includes a scanning circuit 10 connected to a gate bus 102.
4, a hold circuit 108 connected to the source bus 106 for supplying signals, and a TFTIIO serving as a switch element provided at each intersection of a matrix composed of a gate bus and a source bus, and holding a signal. It includes a signal storage capacitor 112 and a liquid crystal display element 114. The active matrix liquid crystal display device temporarily conducts all TFT IIOs on the gate bus 102 in a line-sequential manner, and connects the source bus 106 from the hold circuit 108 to the conductive state.
A signal is provided to each signal storage capacitor 112 via a signal storage capacitor 112 . The supplied signal can excite the liquid crystal until the next frame is scanned. FIG. 8 is a schematic cross-sectional view of a conventional active matrix liquid crystal display device. Referring to FIG. 8, the conventional active matrix liquid crystal display device has polarizing plates 116 and 11 on the outside.
8, a light-transmissive substrate 120, 122 made of, for example, borosilicate glass, a pixel electrode 124 formed inside the substrate 120, 122, and its counter electrode 1.
26 and an insulating layer 128, 130 formed thereon,
Furthermore, liquid crystal alignment films 132 and 134 for aligning the molecular axes of the liquid crystal formed thereon, and the substrate 120 and the substrate 122
, and a liquid crystal 138 sealed in a space surrounded by a spacer 136. A TPT as a switching element is connected to the picture element electrode 124 on the side illuminated by the backlight 140. A color filter 142 is provided between the upper substrate 122 and the picture element electrode 126. FIG. 9 is a view along arrows IX-IX in FIG. 8, and is a plan view showing an example of the arrangement of the picture element electrodes 124 on the substrate 120 and the wiring in the vicinity. Referring to FIG. 9, a TFTllo is connected to the picture element electrode 124. The gate electrode 144 of TFTllo is connected to the gate bus 102. T
A source electrode 146 of FTIIO is connected to source bus 106 . The drain electrode 148 of TFTIIO is connected to the picture element electrode 124. The display operation of the active matrix liquid crystal display device configured as described above will be explained below with reference to FIGS. 7 to 9. In the following description, it is assumed that the liquid crystal 138 is a twisted nematic type liquid crystal (hereinafter abbreviated as TN type liquid crystal), and the polarization axes of the polarizing plate 116 and the polarizing plate 118 are perpendicular to each other. Light rays incident on the liquid crystal display device from the backlight 140 side are polarized in a predetermined direction by the polarizing plate 116. The polarized light beam is incident on liquid crystal 138. LCD 13
When no voltage is applied to 8, the liquid crystal 13
The crystal molecules of No. 8 are oriented in a predetermined direction by liquid crystal alignment films 132 and 134. Therefore, the polarization plane of the light incident on the liquid crystal 138 is rotated by a predetermined angle while passing through the liquid crystal. This rotation of the plane of polarization is called optical rotation. In the case of a TN type liquid crystal, the plane of polarization is rotated by 90° due to optical rotation. Polarizing plate 116.11
8 are arranged so that their polarization axes form an angle of 90@. Therefore, the light that has passed through the liquid crystal 138 also passes through the polarizing plate 118, and when viewed from the side opposite to the backlight 140, that part of the liquid crystal becomes a bright spot. By the way, referring to FIG. 7, it is assumed that a predetermined voltage is applied to the gate electrode 144 of the TFT IIO via the gate bus 102. At this time, TFTIIO becomes conductive. Source bus wiring 1 is connected to the source electrode 146 of TFTllo.
A predetermined voltage is always applied through 06. Therefore, a voltage is applied to the picture element electrode 124 by turning on this TPT. Therefore, the picture element electrodes 124 facing each other with the liquid crystal 138 interposed therebetween
An electric field is generated between the pixel electrode 126 and the pixel electrode 126. This electric field changes the orientation of liquid crystal molecules in the liquid crystal 138. As a result, the backlight 140 causes the liquid crystal 1 to
The polarization plane of the light incident on the liquid crystal 138 after passing through the liquid crystal 138 no longer matches the polarization plane of the polarizing plate 118 . Therefore, the light rays cannot pass through the polarizing plate 118 and do not reach the outside of the liquid crystal display device. The above-mentioned picture element portion of the liquid crystal becomes a dark spot when viewed from the opposite side of the backlight 140. An active matrix drive liquid crystal display device operates on this principle. A desired image or information is displayed by individually operating a large number of picture elements arranged in a matrix over the entire screen by switching using switching elements. Therefore, a defective switching element directly results in a defective display state. Referring to the above example, assume that the source electrode 146 and the drain electrode 148 in the TFT IIO are in a leak state. Since the TPT 110 is always in the same on state, a voltage is always applied to the picture element electrode 124. Therefore, this picture element always becomes a dark spot. On the other hand, it is assumed that even if a predetermined voltage is applied to the gate electrode 144 of TFTllo, TPTllo is non-conductive and does not turn on. No voltage is ever applied to the picture element electrode 124. Therefore, this picture element portion always becomes a bright spot. That is, a defective switching element always causes a defective display state. In order to suppress the deterioration of display quality due to these point defects, the following methods are available. A method of providing a plurality of switching elements in one picture element, a method of dividing one picture element into a plurality of picture element electrodes, and forming one or more switching elements in each divided picture element electrode, etc. be. FIG. 10 shows an example in which two TPTs are provided in one picture element electrode. Referring to FIG. 10, a picture element electrode 150 of an active matrix drive liquid crystal display device includes a first TFT 15.
2 and the second TFT 154 are connected. 1st TF
Both T152 and the second TFT 154 have gate electrodes connected to the gate bus 102 and source electrodes connected to the source bus 106.
- A drain electrode is connected to the picture element electrode 150. The operation of this liquid crystal display device will be explained with reference to FIG. It is assumed that no voltage is applied to each gate electrode of the first TFT 152 and the second TFTI 54 via the gate bus 102. First TFT 152, second TFT
154 are both off. Therefore, the picture element electrode 150
No voltage is applied to. As a result, this picture element portion becomes a bright spot. It is assumed that a predetermined voltage is applied to each gate electrode of the first TFT 152 and the second TFT 154 via the gate bus 102. First TFT 152, second TFT 154
Both are in the off state. A voltage is applied to the picture element electrode 150. As a result, this picture element portion becomes a dark spot. This structure has the advantage that even if one of the two TFTs becomes non-conductive, the picture element electrode 150 can be normally driven by the other normal TFT. Referring to FIG. 10, it is assumed that the first TFT 152 is non-conductive and the second TFT 154 is normal. 1st
TFT 152 is always off. Therefore, the first TFT1
52. When no voltage is applied to the gate electrode of the second TFT 154, this picture element portion becomes a bright spot. It is assumed that a predetermined voltage is applied to each gate electrode of the first TFT 152 and the second TFT 154 via the gate bus 102. Since the first TFT 152 is non-conductive, it is in an off state, and the second TFT 154 is in an on state. A voltage is applied to the picture element electrode 150 by the second TFT 154 . As a result, this picture element portion becomes a dark spot. That is, the picture element electrode 150 operates in the same manner as in normal operation. FIG. 11 shows an example in which one picture element is divided into two picture element electrodes, and one TFT is provided for each divided picture element electrode. Referring to FIG. 11, a first TPT 158 is provided in a first divided picture element electrode 156 constituting this picture element. The second divided picture element electrode 160 constituting this picture element has a second
TFT 162 is provided. Each gate electrode of the first TPT 158 and the second TFT 162 is connected to the gate bus 102, and each source electrode is connected to the source bus 106. The drain electrode of the first TPT 158 is connected to the first divided picture element electrode 156, and the drain electrode of the first TPT 158 is connected to the first divided picture element electrode 156.
The drain electrode of the TFT 162 is the second divided picture element electrode 1.
60. The operation of this liquid crystal display device will be explained with reference to FIG. It is assumed that no voltage is applied to each gate electrode of the first TPT 158 and the second TFT 162 via the gate bus 102. First TPT158, second TFT
162 are both in the off state. Therefore, no voltage is applied to the first divided picture element electrode 156 and the second divided picture element electrode 160. As a result, this picture element electrode becomes a bright spot. It is assumed that a predetermined voltage is applied to each gate electrode of the first TPT 158 and the second TFT 162 via the gate bus 102. First TPT158, second TFT162
Both are turned on. A voltage is applied to the first divided picture element electrode 156 and the second divided picture element electrode 160. As a result, this picture element portion becomes a dark spot. Both the first TFT 158 and the second TFT 162 are connected to the same source bus and gate bus. Therefore, the on/off states of the first TPT 158 and the second TFT 162 are always the same. Therefore, the display states of the first divided picture element electrode 156 and the second divided picture element electrode 160 are always the same. As a result, the first divided picture element electrode 156 and the second divided picture element electrode 160 are displayed as one picture element. With this structure, even if one of the two TPTs becomes defective,
The advantage is that half of the picture elements work normally as long as at least the other half is normal. [Problems to be Solved by the Invention] However, the conventional technology has the following problems. One of the problems is that display failure is likely to occur due to a defective switching element, and there is no means to compensate for this. A case where a plurality of switching elements are provided in one picture element electrode will be explained using FIG. 10 as an example. 1st TF
Assume that there is a leak defect in either the TI 52 or the second TFT 154, and that TPT is always in a conductive state. In this case, a voltage is applied to the picture element electrode 150 regardless of whether a predetermined voltage is applied to each gate electrode via the gate bus 102. Therefore, this picture element always becomes a dark spot and cannot function normally. In order to compensate for this defect, it is necessary to repair the defective TPT during manufacturing or to separate it from the picture element electrode 150. However, the size of TPT is about 10 μm, and it is not possible to repair each TPT one by one, and it is also impossible to measure the characteristics of each TPT. Therefore, it is impossible to identify the defective TPT. Also, if you accidentally replace a normal TPT with the pixel electrode 150,
Separation from the pixel electrode 150 is not allowed because there is a risk that the pixel electrode 150 will become non-conductive. Therefore, it is virtually impossible to separate only the defective TFT from the picture element electrode 150. That is, it is impossible to repair display defects caused by TPT leakage defects. A case where one picture element is divided into a plurality of divided picture element electrodes and a switching element is provided in each divided picture element electrode will be explained using FIG. 11 as an example. Assume that the first TFTI 58 is defective. If the defect is a leak, half of the picture elements will always be dark spots. On the other hand, if the defect is a non-conducting defect, this portion always appears as a bright spot, further deteriorating the display quality. In this case, there is no point in separating the TFT from the divided picture element electrodes since the TFT is originally non-conductive. In addition, if a plurality of TPTs are provided in one divided picture element electrode, the first
This is the same as in Figure 0. In other words, a defective TPT cannot be identified and cannot be repaired. Therefore, the operation of this divided picture element electrode cannot be made normal. As a result, although display defects due to TPT defects are limited to a portion of picture elements, it has been impossible to improve the display defects. The second problem is a decrease in the aperture ratio of the screen. It is necessary to form a black stripe pattern as shown in FIG. 12 between each divided picture element electrode in order to prevent light transmission and obtain screen contrast. Therefore, compared to the case where the picture element is not divided, the aperture ratio is reduced by the area between the divided picture element electrodes. As a result, there are problems in that the brightness of the screen decreases and the clarity of the displayed image also decreases. Recently, in order to improve the display quality of liquid crystal display panels, it is required to increase the number of picture elements. In addition, the increase in the size of liquid crystal display panels is also considered to be a major factor in increasing the number of picture elements. An increase in the number of picture elements also means an increase in the number of picture elements with display defects. Therefore, there is a need for a liquid crystal display device that can suppress the above-mentioned display defects and also has a good screen aperture ratio. Therefore, an object of the present invention is to provide a liquid crystal display device that can achieve high display quality with fewer display defects even when the screen is enlarged. [Means for Solving the Problems] A liquid crystal display device according to the present invention includes a liquid crystal display panel including an arrangement of a plurality of pixel display areas capable of taking at least two display states, each pixel display area having a plurality of predetermined display states. a display driving means that individually drives the display of each divided display area in each pixel display area; and a divided display area connection preparation means for enabling the areas to be connected to each other after the fact.

[Effect]

The liquid crystal display device according to the present invention is configured as described above. Therefore, when a defective switching means is discovered in each divided display area, only that divided display area can be separated from the display driving means if necessary. Furthermore, it is possible to connect the divided display area to another divided display area within the pixel display area to which the divided display area belongs by using a divided display area connection preparation means. By doing so, it is possible to ensure that all the divided display areas within one pixel display area are normally driven by normal switching means. In this case, the divided display area having the defective switching means may be once completely separated from the display driving means. That is, even if one of the plurality of switching means provided in one divided display area is defective, there is no need to identify the defective switching means and disconnect only that switching means. Moreover, the divided display area connection preparation means can be connected by the new picture element electrode itself. This new picture element electrode can be provided over the entire surface of the picture element. As a result, there is no need to provide a black stripe between each divided display area, and the aperture ratio increases. [Embodiment] FIG. 3 is a diagram illustrating the operating principle of an active matrix drive liquid crystal display device according to the present invention. This figure shows a case where the TPT is used as a switching element and a signal storage element is provided. Referring to FIG. 3, the active matrix display device includes a scanning circuit 104 connected to a gate bus 102 and a source bus 1.
Hold circuit 1 connected to 06 and for supplying a signal
08, a first TPT 4 and a second TPT 6 that serve as switch elements provided at each intersection of a matrix composed of a gate bus and a source bus, and a signal storage capacitor 112 for holding a signal. and a liquid crystal display element 2. The active matrix liquid crystal display device sequentially scans the scanning electrodes of the gate bus 102 in a line-sequential manner, temporarily makes all the TPTs 4.6 on one gate bus 1. , provides a signal to each signal storage capacitor 112. The supplied signal can excite the liquid crystal until the next frame is scanned. Among the TPTs, the defective TPT 15 is separated from the liquid crystal display element 12, and the normal third TPT 8 is separated from the liquid crystal display element 1.
Drive 2. 3. FIG. 1 is a plan view of a substrate showing the arrangement of picture element electrodes on the substrate of a liquid crystal display device according to the present invention. FIG. 2 is a sectional view taken along the line ■-■ in FIG. 1. Referring to FIG. 1, the first divided picture element electrode 14 has a first TPT1.
6, the second divided picture element electrode 18 is provided with a second TPT 20 . Referring to FIG. 2, SiN is deposited on the substrate 22.
, or 5i02 or the like is formed. First divided picture element electrode 14 and second divided picture element electrode 18
is provided on the gate insulating film 24. A protective film 26 is formed on the first divided picture element electrode 14 and the second divided picture element electrode 18 so as to cover all the divided picture element electrodes. A contact hole 28 is formed in a portion of the protective film 26 above each divided search electrode by patterning or the like. Then, the divided picture element electrodes 14 and 18 are connected through the contact holes 28.
An integrated picture element electrode 30 electrically connected to the protective film 26 is formed on the protective film 26. FIG. 4 is an enlarged plan view of the vicinity of the TFT 16. 5 is a sectional view taken along the line V-V in FIG. 4. FIG. The configuration of TFTi6 will be explained with reference to FIGS. 4 and 5. A gate electrode 48 is formed on the substrate 22 by etching or the like. Gate electrode 48 and gate bus 10
An anodic oxide film 32 is formed on 2. Furthermore, on top of that
A gate insulating film 24 such as iNx or 5IO2 is formed. A semiconductor layer 34 is provided thereon. semiconductor layer 34
A protective insulating film 36 is formed thereon. Further, on the protective insulating film 36 are an n+-amorphous silicon contact layer 38 and an n+-amorphous silicon contact layer 38.
A source electrode 40 and a drain electrode 42 formed on
and is provided. The drain electrode 42 is connected to the first divided picture element electrode 14. A predetermined voltage is always applied to the source electrode 40 via the source bus 106. When a predetermined voltage is applied from the gate bus 102 to the gate electrode 48, the TFT 10
2 is in the on state. As a result, a current flows from the source electrode 40 to the drain electrode 42. Therefore, a voltage is applied to the first divided picture element electrode 141. Referring to FIG. 1, the first TFT 16 and the second TFT 20
Suppose that both are on. At this time, a voltage is applied to both the first and second divided picture element electrodes 14,18, and as a result, the same voltage is applied to the integrated picture element electrode 30 as well. Therefore, this picture element becomes a dark spot. Further, it is assumed that both the first TFT 16 and the second TPT 20 are off. At this time, the first divided picture element electrode 14
No voltage is applied to the second divided picture element electrode 18. Therefore, no voltage is applied to the integrated picture element electrode 30, and this picture element becomes a bright spot. Now, assume that the first TFT 16 has a leak defect. The fact that the TFT 16 has a leakage defect at the time when the first divided picture element electrode 16 and the second divided picture element electrode are formed means that This can be easily seen from the electrical relationship between them. The following actions are taken for the TFT 16 in which a defect has been found. That is, the first divided picture element electrode 14 and the first TFT 16
The first divided picture element electrode 14 may be separated from the first TFT 16 using a laser or the like near the connection point. The cutting portion 44 in FIG. 1 shows an example of such cutting. This is 4 in Figure 4.
This corresponds to the part indicated by the dashed dotted line in 4-44. At this time, it is assumed that a predetermined voltage is applied to the gate electrode 30 via the gate bus 102. Referring to FIG. 1, the first TFT 16 and the first divided picture element electrode 14 are separated. Therefore, no voltage is applied to the first divided picture element electrode 14 by the first TFT 16. On the other hand, the second TPT 20 is turned on, and a predetermined voltage is applied to the second divided picture element electrode 18. As a result, a predetermined voltage is also applied to the integrated picture element electrode 30, and this picture element becomes a dark spot. On the other hand, when there is no voltage applied to the gate electrode 30, the second TPT 20 is turned off. Therefore, no voltage is applied to the first divided picture element electrode 14, the second divided picture element electrode 18, and the integrated picture element electrode 30. As a result, this picture element becomes a bright spot. In addition, if the first TFT 16 is non-conductive, the first TFT 16
This is similar to the case where the TFT 16 and the first divided picture element electrode 14 are separated. Further, it goes without saying that the same operation as described above is performed even when there is a defect in the second TFT 20. As a result, in the liquid crystal display device of FIG.
It is possible to detect T and separate it from the picture element, and the picture element operates normally using other normal TPTs. That is, it is possible to remove the influence of defects in TPT formed during the manufacturing process and to make the display state normal. Furthermore, since the integrated picture element electrode 30 can be formed to cover the entire picture element, there is no need to form black stripes between the divided picture element electrodes. As an example of the black stripe pattern, a pattern as shown in FIG. 6 can be considered. By adopting such a black stripe pattern, the aperture ratio increases, and at the same time, the brightness and clarity of the screen increases. Furthermore, it is possible to form the integrated picture element electrode on a surface three-dimensionally different from the surface on which the source bus is formed. Therefore, the possibility of a short circuit between the integrated picture element electrode and the source bus is small. Therefore, there is a margin for positional accuracy of patterning, etc., and manufacturing is easy. Furthermore, for the same reason, it is possible to make the integrated picture element electrode larger than in the case where the picture element is not divided, and the aperture ratio can be further improved. Note that this invention is not limited to the above-described embodiments. For example, each divided picture element electrode may be provided with a plurality of switching elements. In this case, the fact that there is a defect in the switching element provided in the divided picture element electrode can be detected in the same way as when there is only one switching element. Furthermore, it is not necessary to specify which of the plurality of switching elements is defective. That is, it is only necessary to separate the divided picture element electrode having a defective switching element from the display driving means. To do this, all switching elements, including normal switching elements, may be separated from this divided picture element electrode. This can be done easily. Further, in this embodiment, each picture element of the liquid crystal display device is divided into two divided picture element electrodes, but the number of divisions is not limited to two, but may be divided into a plurality of parts. Furthermore, although TPT is used as the switching element in this embodiment, any other element may be used as long as it can drive a picture element. Furthermore, in this example, the contact hole is
Although one pixel electrode is formed for each divided picture element electrode, the number and shape thereof are not limited as long as each divided picture element electrode and the integrated picture element electrode can be electrically connected. For example, it may be one contact hole spanning a plurality of divided picture element electrodes. In addition, in FIG. 4, the TFT and the divided picture element electrode are 44-
Separated by 44 lines. However, TPT and source bus 1
It goes without saying that the same effect can be obtained even if the 06 and 06 are separated by a dashed dotted line indicated by 46-46. [Effect] The liquid crystal display device includes a liquid crystal display panel including an array of a plurality of pixel display areas capable of taking at least two display states, each pixel display area including a plurality of predetermined divided display areas. , in each pixel display area, a display driving means for individually driving display of each divided display area, and a display driving means provided in each divided display area, which is capable of connecting each divided display area in each pixel display area to each other after the fact. and split display area connection preparation means for. The liquid crystal display device according to the present invention is configured as described above. Therefore, when a defective switching means is discovered in each divided display area, only the necessary divided display area can be separated from the display driving means. Further, it is possible to connect the divided display area to another divided display area within the pixel display area to which the divided display area belongs by using a divided display area connection preparation means. By doing so, all the divided display areas within one pixel display area can be normally driven by normal switching means. In this case, the divided display area having the defective switching means may be once completely separated from the display driving means. That is, even if one of the plurality of switching means provided in one divided display area is defective, there is no need to identify the non-defective switching means and disconnect only that switching means. Moreover, the divided display area connection preparation means can be connected by the new picture element electrode itself. This new picture element electrode can be provided over the entire surface of the picture element. As a result, there is no need to provide a black stripe between each divided display area, and the aperture ratio increases. Therefore, even if a defect occurs in the switching means, the occurrence of display defects due to its influence can be suppressed, and display quality can be improved. As a result, even if the number of picture elements of a liquid crystal display panel increases, a liquid crystal display device with high display quality can be manufactured with a sufficiently high yield. In other words, it is possible to provide a liquid crystal display device that has fewer display defects even when the screen is enlarged and can achieve high display quality.

[Brief explanation of the drawing]

FIG. 1 is a plan view showing the arrangement of picture element electrodes of a liquid crystal display device according to the present invention, FIG. 2 is a partially enlarged sectional view of FIG. 1, and FIG. 3 is a liquid crystal display device according to the present invention. FIG. 4 is a partially enlarged plan view of the vicinity of the TPT provided in the picture element electrode, FIG. 5 is a cross-sectional view of FIG. 4, and FIG. 6 is a diagram of the liquid crystal according to the present invention. This is an example of a black stripe pattern used in a display device, FIG. 7 is a diagram of the operating principle of a conventional active matrix drive liquid crystal display device, and FIG. 8 is a schematic cross-sectional view of a liquid crystal display panel. ! FIG. 9, FIG. 10, and FIG. 11 are plan views showing examples of the arrangement of conventional picture element electrodes, respectively.
The figure shows an example of a conventional black stripe pattern. In the figure, 2.12.114 is a liquid crystal display element, 4.6.8.
16.20.110.152.154.158.162
is TFT, 10 is defective TFT, 14.18.156.1
60 is a divided picture element electrode, 102 is a gate bus, 104 is a scanning circuit, 106 is a source bus, 108 is a hold circuit,
124, 126, and 150 represent picture element electrodes, and 30 represents an integrated picture element electrode. In addition, in the figures, the same reference numerals indicate the same or corresponding parts. (2 others) 1st design 2nd 3rd design 1q Imabu Sou 11 bond 1ji Shashin burnt fork and other feet〉77 hole No. 40 40゛Source Q unse%5 Figure 32 Pj I5 Sleeve 1 Pekkatansara 34〒Gutter Figure 7 Exit O TFτ 1+4. ：Namisho Nanaiko also 6 figures 7゛° Nku Strive Batashi Part 8↑! ! ↑ ↑ Law 140: Bamakurite No. 9 picture! Figure 10

Claims (1)

Scope of Claims: A liquid crystal display panel including an array of a plurality of pixel display areas capable of taking at least two display states, each of the pixel display areas including a plurality of predetermined divided display areas, In each of the pixel display areas, a display driving means for individually driving the display of each of the divided display areas; A liquid crystal display device comprising a split display area connection preparation means for making connection possible.