JPS6150196A - Solid display unit - 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 [Conventional Field of Application] The present invention aims to solidify the display section of a microcomputer, word processor, television, etc. by providing a liquid crystal display panel.

``Prior Art'' For solid-state display panels, a system in which each picture element is controlled independently is effective for large-area displays. As a panel using such an active element, as shown in Fig. 4, there is a picture consisting of one insulated field effect semiconductor device (referred to as IGF) (9) and a liquid crystal element (4) connected in series with it. It has a matrix configuration in which elements are connected to x and Y wiring.

"Problems to be Solved by the Invention" However, in a display panel using this IGF, the number of masks required for the manufacturing process is 6 to 8, and therefore, the manufacturing yield is expected to be low.

Furthermore, since the semiconductor for this IGF has a thin film structure, it is mainly manufactured using an amorphous semiconductor, but the physical properties of the interface between the amorphous semiconductor and the gate insulator have not been fully elucidated.

This has caused fundamental problems such as variations in the threshold voltage of the IGF.

"Means for Solving the Problem" In order to solve the problem, the present invention does not use IGF as a system for controlling active elements, and uses sufficient technology to use diodes, especially solar cells, which is one of the effective fields of amorphous semiconductors. The main method is to use a PIN type diode which has a high storage capacity.

When such a diode uses forward charge, its build-in (rise) voltage is approximately constant at about 0.7V, and there is no manufacturing variation. Since the physical properties of the insulating film-semiconductor interface are not used, there is no instability in temperature treatment and B-T treatment (bias-temperature) treatment.

Furthermore, the present invention provides such a diode with X! Il! L% and Y
At least two are connected in series in the same direction between the wires,
It is connected to one electrode of the liquid crystal display from its midpoint. Representative examples of such structures are shown in FIGS. 1 and 2.

Since the electrode of the liquid crystal is made from this midpoint, it is easy to control the AC bias to the liquid crystal by controlling the level (11) (step 2) of the other electrode of the liquid crystal, and it is also possible to control the gradation. have

"Function" Furthermore, as shown in Figure 2, the electrode of the other liquid crystal is divided into three parts, each divided into red (referred to as R) and green (G).
By passing the voltage through a blue (referred to as B) filter, voltage can be applied independently on two axes to that level. Therefore, it has the feature of being able to perform gradations for R, G, and B.

Furthermore, the number of masks required in the process to produce this pattern may be four. Therefore, the manufacturing yield is higher than that of the 6-'8 IGF system.

"Example 1" FIG. 1 shows the circuit of the invention.

In the drawing, the picture element (1) is the first diode (2).

The second diodes (3) are connected to each other and the midpoint (25)
It is connected to one electrode of the liquid crystal (4). Also the first
The diodes are the address lines (5) and (6) of the X wiring.
The other second diode is connected to the data lines (7) and (8) of the Y wiring. This X wiring and Y
Both wirings are provided on the same glass substrate side, and the liquid crystal (4)
The other electrode is provided on the opposite glass substrate side,
The Z coordinates are matched. This Z axis may be the entire surface, it may be linearly butter kneaded parallel to the X wiring, or it may be provided parallel to the Y wiring, each of which is determined depending on the usage.

Such picture elements are arranged in a matrix, 2×2 in the drawing.
And so. This is useful for scaled-up display devices such as (
640x 525) also has the same technical idea.

In FIG. 1, writing (W) and saving (S) signals.

The erase or rewrite (E) signal is, for example, (1
, 1) can be performed selectively as shown in the table below.

Thus, a predetermined voltage is selectively applied to (1,1).

By adding it to each wiring of Y, the liquid crystal becomes transparent r
lJ, and other picture elements could be made opaque rOJ.

By repeating this selection, it may be possible to write, hold, and erase the dents for other picture elements as well. This voltage (■) is generally 2.7V or higher for liquid crystal drives.
NterONJ rTransparent J, r at 1.9V or less
Since it has "OFF Jr opacity" as its physical property, V=3.0V, for example. Further, by applying this voltage as an alternating current in synchronization in a matrix system, alternating current driving can be achieved. Furthermore, it is effective to set the Z-axis voltage to V/2±ΔV and vary this voltage to create gradations.

"Example 2" The circuit of this embodiment is shown in FIG.

The basic structure in the drawing is the same as that in FIG.

However, in FIG. 2, the other electrode side of the liquid crystal is connected in the X or Y direction (X direction in the drawing) by three wires, and these are (11-1, 11-2, 1l-3) or (12 -1, 12-2, 12-3> is provided as the Z axis.

In addition, It(13), G
(14), B (15) color filter (10)
is provided. Conventionally, if a full-color one-sided method was to be performed using an IGF, one IGF was required for each picture element of the filter. However, in the present invention, only one picture element (1) is required for each of R, G, and B.
Further, this filter may also be of a dot type, and can be provided in a line corresponding to the Z axis, and the number of active elements required for 173 can be substantially reduced.

In addition, another feature is that the Z-axis decoder (22) can also control the gradation for each picture element.

The driving mechanism for applying the voltage of i''ONJ rOFF J of the liquid crystal to each picture element is the same as in the first embodiment.

``Example 3'' This example is as shown in FIG. 3(A).
The diode ring (29) has two diodes arranged corresponding to one diode.

With this configuration, when writing using the X-axis (5) and Y-axis (7), a current product is involved, but it can be driven in the same way as in the first embodiment.

In addition, in Fig. 3 (B), diodes are installed in parallel, and the wiring pattern is changed in order to make the defective diodes (indicated by YAG laser light (wavelength 0.53
mm.

(pulse width 30 ns or less) (31), (31”
) to prevent it from functioning.

"Effects" As shown above, the present invention uses diodes to construct an active matrix. Therefore, patterning can be performed with an extremely small number of masks (4 masks), and the manufacturing yield can be improved. can.

Since the forward characteristics of a diode are used, there is little variation in the process.

Since the liquid crystal is connected from the midpoint of the two diodes, it is easy to control gradation.

[Brief explanation of drawings]

1 and 2 show the circuits of the liquid crystal display panel of the present invention. FIG. 3 shows another example of the present invention. FIG. 4 is a circuit diagram of a conventional liquid crystal panel.

Claims (1)

[Claims] 1. In a macrox configuration including a plurality of wirings in the X direction and a plurality of wirings in the Y direction, a first wire connected to one of the wires
and a second diode connected in the same direction as the diode, the diode is connected to the other wiring, and a liquid crystal display is connected to the middle point where the first and second diodes are connected to each other. One electrode of the liquid crystal is connected to the other electrode of the matrix, and the other electrode of the liquid crystal is connected to the
1. A solid-state display device, characterized in that it is connected to other electrodes for liquid crystal display that are arranged in a direction or in common. 2. In a Macrix configuration with multiple wires in the X direction and multiple wires in the Y direction, the first wire connected to one wire
and a second diode connected in the same direction as the diode, the diode is connected to the other wiring, and a liquid crystal display is connected to the middle point where the first and second diodes are connected to each other. A solid-state display device, characterized in that one electrode of the liquid crystal is connected and provided, and the other electrode of the liquid crystal is divided into three, and these are arranged in the X or Y direction of a matrix. 3. A solid-state display according to claim 2, characterized in that the other three divided electrodes of the liquid crystal are each provided with red, green, and blue filters corresponding to the transmitted light. Device.