JPS63303322A - Liquid crystal display device - Google Patents

Abstract

PURPOSE:To prevent a defective liquid crystal display by short circuiting of switching means by connecting plural pieces of the switching elements in parallel to respective picture element electrodes and connecting resistance elements in series to the respective switching elements. CONSTITUTION:Plurals pieces of one end of a 1st switching unit 5 connected in series with two pieces of diodes 3 and one end of the 2nd switching unit 6 connected in series with two pieces of diodes 4 having the characteristics reverse from the characteristics of the diodes 3 are arranged respectively in parallel to line electrode wirings 1 and the other ends are commonly connected to a line electrode 8. Resistors 9, 9 are interposed respectively in series to the diodes 3, 4. The resistance values are so set that the off voltage impressed on a liquid crystal layer is kept below the threshold value of the liquid crystal by the resistor 9 and the on voltage impressed on the liquid crystal layer is increased above the threshold value of the liquid crystal by the resistor 9 connected in parallel thereto when a piece of the diode 3 is short circuited.

Description

DETAILED DESCRIPTION OF THE INVENTION "Field of Industrial Application" The present invention relates to a liquid crystal display device, and particularly relates to a nonlinear element (
Related to active matrix liquid crystal display devices (Tai-auto, etc.).

[Prior art 1] Conventionally, a so-called active matrix type liquid crystal display device in which a nonlinear element such as a diode is arranged as a switching means for each pixel and the liquid crystal of each pixel is driven by the switching means is shown in FIG. The structure shown in (Togashi et al., TV Science and Technology Report, Vo.
l, 8, NO, 36, i”, 13 (1,984)
), or one with the configuration shown in Figure 7 (N
, 5zydlo, et, al, ; Proc,
of the JAPAN DISPLAY '83
．． P, 4] 7 (1983)) is known.

The one shown in FIG. 6 consists of two
Two sets of so-called diode rings constructed by connecting two diodes F'D in parallel are used, and a so-called two-stage diode ring, in which these are connected in series, is used as a switching element. One end of this switching element is commonly connected to the row electrode wiring p, and the other end is connected to each row electrode plate m. On the other hand, the column electrode plate n installed opposite to the moe travel electrode plate m is connected to the column electrode wiring q, and furthermore, the row electrode wiring p is connected to the scanning circuit S.
The column electrode wiring q is connected to a signal hold circuit I, respectively. The switching element is actuated by the control voltages supplied from these circuits S and H, and the liquid crystal I provided between the electrode plates m and n is driven.

In addition, the device shown in FIG. 7 uses a so-called back-to-back diode, which is constructed by connecting two diodes of opposite polarity in series, as a switching element. Since it is the same as that shown in the figure, its explanation will be omitted.

"Problems to be Solved by the Invention" However, in the active matrix type liquid crystal display device using the conventional diode (nonlinear element) as a switching means, it is difficult to compare the incidence of defective products due to short circuit to diode-1. The problem was that the yield rate during production was poor.

The present invention has been made in view of the above-mentioned circumstances, and has as its object the provision of a liquid crystal display device that can achieve improved yields.

``Means for Solving the Problems'' In order to solve the above problems, the present invention seals liquid crystal between two substrates, and each pixel electrode provided on each of these substrates so as to face each other. The voltage to be applied is 1 or 2
In a liquid crystal display device in which the liquid crystal of each pixel is controlled by a switching means constructed by arranging a plurality of switching units in series made of the above nonlinear elements, a plurality of switching units are arranged in each pixel name pole as described in 1iij. The present invention is characterized in that two switching means are connected in parallel, and a resistance element is connected in series to each of these switching means.

Here, the switching unit may be, for example, a diode ring constituted by two diodes arranged in opposite polarity connected in parallel. Alternatively, the switching unit may be a single diode, and the 1iff switching means may be a back-to-back diode formed by connecting two diodes with opposite polarities in series. It will be done. Further, as the switching means, metal insulating film metal (MTM) element r., zinc oxide (Z, nO)
Of course, well-known nonlinear two-terminal elements such as varistors can be mentioned.

Hereinafter, a liquid crystal display device of the present invention will be explained with reference to the drawings.

FIG. 1 is a diagram showing a schematic configuration of a liquid crystal display device according to the present invention using a two-stage diode ring as a switching means. In FIG. 1, reference numeral 1 represents a row electrode wiring, and reference numeral 2 represents a column electrode wiring formed to intersect with the row electrode wiring 1. In FIG. To this row electrode wiring 1, one end of a first Swiss diodes 3.3, each consisting of two diodes 3.3 arranged in the same polarity and connected in series, are connected in parallel. and these diodes 3
．． 6. A second switching unit in which two diodes F'4.4 arranged in opposite polarity to 3 are connected in series.
6. The - end of the first switching unit 5.5
, · are connected in parallel. That is, the first switching unit 5 and the second switching unit 6 form a pair to form a two-stage diode ring 7 serving as a switching means. These first
The other ends of the switching unit 5 and the second switching unit 6 are commonly connected to the row electrode plate 8.

A resistor 9.9 is connected in series and interposed in front of each of the diodes 3.4.

Then, on one glass board, the row electrode wiring I,
A large number of pixel portions consisting of diode rings 7, 7, and row electrode plates 8 are formed in a matrix. iτj
The write electrode wiring 1 is formed for each row of these seven tricks, and is commonly connected to the scanning circuit 11.

Similarly, the column electrode wiring 2 is placed on the other glass substrate.
A large number of pixel portions each including a column electrode plate 10 and a column electrode plate 10 are formed in a matrix. The column electrode wiring 2 is formed for every 111th column of this matrix and is commonly connected to the signal hold circuit 12. These two glass substrates are superimposed so that the row electrode wiring 1 and the column electrode wiring 2 are crossed and facing each other, and the row electrode plate 8 and the column electrode plate 10 are facing each other. At the same time, liquid crystal is sealed between these two glass substrates, thereby forming a liquid crystal layer 13 between the two electrode plates 8 and 10.

Next, the structure of the pixel portion formed on one of the glass substrates and consisting of the row electrode wiring 1, the diode ring 7, and the row electrode plate 8 will be explained in more detail with reference to FIGS. 2 and 3. . In Figures 2 and 3, reference numeral 1
4(j) It is a transparent glass substrate, and on the surface of this glass substrate 14, a large number of strip-shaped row electrode wirings 1 formed in a foil shape by depositing aluminum are formed in parallel at regular intervals. , between these row electrode wirings 1, which form a substantially rectangular shape in plan view, are made of indium, tin oxide (TTO).
A large number of transparent conductive row electrode plates 8 are formed in the form of foils by depositing. A matrix pattern is formed on the glass substrate 14 by the row electrode wiring 1 and the row electrode plate 8.

A plurality of anode electrodes 15, [5 made of aluminum extend from the row electrode wiring 1 and are connected to the anode of the diode 3 via a resistor 9 such as a tantalum oxide film. This guide 3 is a so-called pin junction diode made of amorphous silicon, and is an ITO film 16 formed in a foil shape on a glass substrate 14F.
They are stacked one on top of the other with their cathodes in contact with each other. The foil-shaped resistor 9 is formed on the anode side of the diode 3. In addition, the 11゛0 film 16
One end of a cathode electrode 17 made of aluminum is connected to the diode 1, and the other end of the cathode electrode 17 is connected to the diode 1 through a resistor 9 such as a tantalum oxide film.
The diode 3 is connected to the anode of the diode 3 connected in series with the same polarity as the diode 3. This diode 1' 3 also has the same structure as the diode 3 described above, and its cathode is connected to the row electrode plate 8. Incidentally, reference numeral 18 denotes silicon oxide (SiO7) formed to cover the diode 3.3.
), etc. And 11
The diode 3.3 mentioned above is constructed by dividing the diode D installed in the conventional liquid crystal display device into a predetermined number (N in the illustrated example).
The area occupied above is approximately 1/N of that of the conventional tie auto D.

Note that the configuration of the diodes 4 and 4 arranged with opposite polarity to the diode 3 (J) is similar to the configuration described above in which the diodes are connected in the opposite direction, so illustration and explanation are omitted. The structure of the other glass substrate on which the electrode wiring 2 and the column electrode plate 10 are formed is similar to the above-mentioned glass substrate 14 on the - side, with the diodes 3.3 omitted, so illustration and description thereof will be omitted. .

In the liquid crystal display device having the above structure, the liquid crystal layer I3 is driven by supplying control voltages from the scanning circuit 11 and the signal bold circuit I2, and various displays are performed.

Here, the resistance value of the resistor 9 will be explained. According to the results of the inventor's test i=1, the short circuit occurs in the diode 3.4 because a defect such as a pin pole that causes dielectric breakdown occurs in the diode 1' 3.4.

Moreover, the size of these pinopoles is mainly 571 m or less, and their occurrence is about 01 to 1 piece/mm'.

Therefore, for example, even if the conventional diode D is divided into 20 parts of about 110l to form a small diode 3.4,
Among these small diodes 3.4, the number of small diodes 3.4 in which a short circuit occurs is probability 0 to 1. Therefore, the minimum resistance value of the resistor 9 is the voltage applied to the liquid crystal layer 13 by the resistor 9 connected in series to this diode 3 (or diode 4) when one diode 3 (or diode 4) is short-circuited. Any resistance value such that the O PF voltage is suppressed below the threshold value of the liquid crystal may be used. Further, the resistor 9.9 has N with respect to the row electrode wiring 1.
Since these resistors 9.9 are connected in parallel, if the resistance value of each of these resistors 9.9 is r, the resistance value R of the resistors 9.9 as a whole is R-r/N. Therefore, the maximum resistance value of the total resistance value H is the total resistance value R such that the ON voltage applied to the liquid crystal layer 13 by the total resistance value R when the diode 3.4 is conductive becomes the threshold value of the liquid crystal. It is sufficient that the maximum resistance value of the resistor 9 is equal to or less than RXN. Therefore, according to the present invention, it is possible to prevent defects in liquid crystal display due to short circuits of nonlinear elements, and to improve yield.
It becomes possible to realize a liquid crystal display device that can realize this.

Note that the position where the resistor 9 is formed is not limited to the example shown above, and for example, as shown in FIG.
5. A portion of the cathode electrode 17 may be cut and the resistor 9 may be formed to cover the cut portion.

Next, FIG. 5 is a diagram showing a schematic configuration of a liquid crystal display device according to the present invention using back-to-back diodes as switching means. In FIG. 5, one ends of a plurality of resistors 29, 29, . . . are connected in parallel to the row electrode wiring 21, and the other ends of the resistors 29, 29, . 23, is connected to the cathode of . These diodes 23.23, .
4.24, are connected to the cathodes of these diodes 24.24, and the anodes of these diodes 24.24 and 29.2 are connected to the cathodes of
9, . . , are commonly connected to the row electrode plate 28.

Further, a column electrode plate 30 is connected to the column electrode wiring 22, and a liquid crystal layer 33 is formed by sealing liquid crystal between the row electrode plate 28 and the column electrode plate 30. The row electrode wiring 21 and the column electrode wiring 22 are commonly connected to a scanning circuit 31 and a signal bold circuit 32, respectively. I-L
In the configuration, the diodes 23 and 24 are back-to-back diodes 2 which are switching means of the liquid crystal display device.
7.

The structure of the liquid crystal display device shown in FIG. 5 is similar to the liquid crystal display device shown in FIGS. Since they have exactly the same configuration, illustrations and explanations will be omitted. 3. In this illustrated example, 1) the liquid crystal display device shown in FIGS. Nonlinear elements (
Since the number of diodes (1.) is small, it becomes more advantageous in terms of open rate, yield, and productivity.

Note that the shape, dimensions, etc. of the liquid crystal display device of the present invention are not limited to the illustrated examples, and can be implemented with appropriate changes. - As an example, one pixel electrode (row electrode plate 8.
The number of switching means (diode ring 7, back-to-hack diode 27, etc.) provided in 28) is arbitrary and may be appropriately determined in consideration of various conditions such as response characteristics and yield. Further, the area occupied by the diode 3.4 on the glass substrate 14 does not have to be l/N of the area of the conventional diode D, and may be determined as appropriate based on the probability of occurrence of defects due to pinholes, etc. That's fine.

Furthermore, the nonlinear elements constituting the switching unit are not limited to diodes as in the illustrated example, but metal insulating film metal (MIM) elements or zinc oxide (
Of course, the nonlinear two-terminal element may be appropriately selected from well-known nonlinear two-terminal elements such as a ZnO (ZnO) varistor depending on its intended use.

"Effects of the Invention" As described in detail below, the present invention connects a plurality of switching means in parallel to each pixel electrode of a liquid crystal display device, and connects a resistor element in series to each of these switching means. Compared to a structure in which a single switching means is connected in series to the pixel electrode, it is possible to prevent defects in the liquid crystal display due to short circuits between the switching means and nonlinear elements. This makes it possible to realize "improvements in yield."

[Brief explanation of the drawing]

1 to 3 are diagrams showing an example of a liquid crystal display device according to the present invention, in which FIG. 1 is a circuit diagram thereof, FIG. 2 is a plan view thereof, and FIG. 3 is a 4 is a sectional view showing another example of the liquid crystal display device according to the present invention, and FIG. 5 is a sectional view showing another example of the liquid crystal display device according to the present invention. 6 is a circuit diagram showing an example of a conventional liquid crystal display device, and FIG. 7 is a circuit diagram showing an example of a conventional liquid crystal display device. 3.4 Diode (nonlinear element or switch nog unit), 5 1st switching unit, 6
2nd switching unit, 7 diode ring (switching means), 8.28... row electrode plate (
pixel electrode), 9.29 ・Resistor (resistance element), 10
．． 30 Column electrode plate (pixel electrode), 13.33 Liquid crystal layer, 14 Glass substrate, 27...Pack-to-back diode (switching means) Fig. 3 Fig. 6

Claims (3)

[Claims] (1) A liquid crystal is sealed between two substrates, and a plurality of switching units each consisting of one or more nonlinear elements are connected in series to apply voltage to each pixel electrode provided on each substrate so as to face each other. In a liquid crystal display device in which a plurality of switching means are connected in parallel to each pixel electrode, a plurality of switching means are connected in parallel to each pixel electrode, and a plurality of switching means are connected in parallel to each pixel electrode. A liquid crystal display device characterized in that each of the means has a resistive element connected in series. (2) The liquid crystal display device according to claim 1, wherein the switching unit is a diode ring configured by connecting in parallel two diodes arranged with opposite polarities. (3) A patent characterized in that the switching unit is a single diode, and the switching means is constituted by a back-to-back diode in which two diodes arranged with opposite polarities are connected in series. A liquid crystal display device according to claim 1.