JPS5913278A - Active matrix liquid crystal display - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to the structure of a multi-row, multi-digit active matrix liquid crystal display device.

A conventional active matrix liquid crystal display device is often explained using an equivalent circuit as shown in FIG. Each pixel is provided with a switch element 11Q, and a signal from a control signal line 16 that sends a signal to control the opening and closing of the switch is used to
It has a function of opening and closing a switch to read a display signal from the display signal 11111 into a pixel and hold it.

The counter electrode 12 is a full-surface NESA electrode. (Hereinafter referred to as the common electrode.) Figure 2 shows the potential 2 of the common electrode mentioned earlier.
2 and the potential 2 read into the pixel and applied to the liquid crystal layer.
1 is a diagram showing 1. Conventional active matrix devices like this form a switch element for each pixel, so...
The number of switch elements becomes enormous. For example, if there are 20 vertical lines and 20 horizontal lines each, the number of pixels is 40,000, and the number of switch elements in each pixel is also 40,000, which is a huge number. It is difficult to fabricate such a huge number of devices without defects, and conventional devices have a drawback of extremely low yields. In FIG. 3, two switch elements are fabricated in each pixel in order to improve the yield of the conventional device.

In this way, the number of switch elements can be doubled or fabricated, and either control signal line 55 or 56 can be selected and used depending on the defect, thereby reducing defects caused by the switch element and increasing yield. It is. There were two drawbacks in this case:

(1) Since the number of elements to be fabricated doubles, the number of defective locations also increases, and the yield is not as high as expected.

(11) Since two elements must be formed in the same pixel and twice as many control signal lines are required, the area occupied by the liquid crystal driving electrode in the pixel can be reduced accordingly. In other words, the present invention eliminates the above-mentioned conventional drawbacks, which lead to a decrease in contrast as a liquid crystal display device.The purpose of the present invention is to reduce the number of switching elements in an active matrix liquid crystal display device and improve the yield. By increasing the number of switching elements and reducing the number of switching elements, the electrode surface for driving the liquid crystal becomes wider, making it possible to improve contrast.

FIG. 4 is a conceptual diagram of an active matrix liquid crystal display device according to the present invention.

A control signal line 45 that sends a control signal to control opening and closing of the switch element 48, a display signal line 41 that sends a display signal to the switch element 48, the switch element 48, and a display electrode 424 are formed on one side substrate, and the opposite substrate. Upper electrode 414~
Reference numeral 418 intersects the display electrode 424 at a substantially right angle to form a panel. Electrodes 414 to 41 on the counter substrate
A plurality of 8 are provided. FIG. 5 shows the temporal relationship of signals on each signal line. A control signal 51 is applied to the control signal line 45 , and a control signal 52 is applied to the control signal line 46 . In this way, the control signals 51, 52, 53, 54, . . . are sequentially applied to the control signal line. Since the display signal 55 is applied to the display signal l1I41, the switching transistors 48 and 43
The signals read and held in the display electrodes 424 and 425 by 1 are 56 and 57, respectively. At the same time, the signal applied to the electrode 414 of the counter substrate is 258, and the signal applied to the electrode 415 is 59. □Signal waveform 5
10 and 511 are the horizontal axes, ie, the time axes, of the signal waveforms so and s9, respectively, reduced. By controlling the signals at each location in this way, the signals applied to the liquid crystal layer are such that a signal waveform of 512 is applied to the liquid crystal layer 49, and a signal waveform of 513 is applied to the liquid crystal layer 410. is applied.

For the signal waveform applied to the liquid crystal layer 49, the liquid crystal
In contrast to a signal waveform applied to the liquid crystal layer 410 without lighting, the liquid crystal is turned on. The signal waveform finally applied to the liquid crystal layer has the same waveform as the signal applied by the flat pressure averaging method. In this example, an example is shown in which the driving voltage is CV)-C37), but in FIG. fT+1)V
Note: The voltage before par indicates the voltage when the voltage averaging method is not selected, and (J'''T+1)■ indicates the voltage when it is selected.) Driving is optimal.

The present invention, which has a structure in which switching elements such as transistors are not created for each pixel, has the following advantages.

(1) Since the number of devices to be fabricated is reduced, yields are dramatically improved.

(11) Since the number of switch elements can be reduced, it is possible to form extra switch elements for the purpose of providing redundancy, and furthermore, the yield can be ensured.

(III) Since there are fewer switching elements, there are fewer parts such as wiring that cause deterioration of display quality, which helps improve contrast.

As described above, the present invention is highly effective in the sense that it is possible to dramatically improve the degree of multiplexing of four trixes using active elements. Although the present invention uses a one-channel transistor as a switch element, any element having a switch function falls within the scope of the present invention.

[Brief explanation of drawings]

FIG. 1 is a conceptual diagram of a conventional active matrix liquid crystal display device. FIG. 2 shows voltages applied to the liquid crystal layer of a conventional active matrix liquid crystal display device. FIG. 3 is an example of a conventional active matrix liquid crystal display device in which switch element redundancy is provided to improve yield, and FIG. 4 is a schematic diagram of a liquid crystal display device of the present invention. Fifth
This figure is a diagram showing the temporal relationship of each signal waveform of the liquid crystal display device based on FIG. 4. 11-15... Display signal lines 16-19... Control signal line 110... Switch element 111.
......Liquid crystal layer 112...Pa...
...Counter substrate electrode (common electrode) 21...
...... Potential 22 applied to the liquid crystal layer...
...... Common electrode potential 31 to 34...
...Display signal line 311, old...Switch element 312...
...Old...Liquid crystal layer 313...Old...Common electrode 314...Old...Switch elements 41 to 44 for providing redundancy...・Display signal lines 45 to 47...Control signal lines 48e45j...Switch elements 49 to 415, 426 to 450...Liquid crystal layer 41
4-418, 419-423... Counter substrate electrode 424, 425... Pixel electrode 51-54... Control signal waveform 55... Display Signal waveform 56
... Town... Signal 57 read into display electrode 424 and held... Town old and old... Signal 58 read into display electrode 425 and held...・Signal 59 applied to counter substrate electrode 414 ・Counter substrate electrode 41
Signal 510 applied to 5.58 The horizontal axis of 511...59 is compressed and drawn. Figure 512......Liquid crystal layer 4
Signal 513 applied to liquid crystal layer 410 Signal device applied to liquid crystal layer 410 Applicant Suwa Seikosha Co., Ltd. Agent Patent attorney Tsutomu Mogami No. 1 Figure 2 Hh 9 r; -8-1-? : 2nd ward old school

Claims (1)

[Claims] (1) In a liquid crystal display device in which a liquid crystal layer is sandwiched between two upper and lower substrates, a switch element is formed on one of the substrates, and the other substrate (counter substrate) is
This active matrix liquid crystal display device is patented in that a liquid crystal panel in which display electrodes are formed in the shape of a drive has the following structure. (a) The switch element is connected to a control signal line that sends a control signal for controlling the opening and closing of the switch element, and a display signal line that sends a display signal. The direction of the striped electrodes and the control signal line are approximately parallel. (Iff) A pixel electrode is connected to each of the switch elements, and each pixel electrode faces the plurality of striped electrodes.