JPH0452684A - Driving method of liquid crystal display panel - Google Patents

Abstract

PURPOSE:To increase the colors of a color display on an inexpensive liquid crystal display panel by synchronizing a driver IC with respective switching elements of the liquid crystal display panel, and dividing one output of the former into source data with time and supplying them to plural source lines. CONSTITUTION:The driver IC 13 sends source data out of respective data lines 14 to an output circuit 18 through flip-flop circuits 15, latch circuits 16, and 1st switching elements 17. At this time, the elements 17 are turned ON in order with a gate control signal S1 and the circuit 18 turns ON desired switching circuits in order according to the source data to output a desired voltage in an intermediate-level voltage. Then the liquid crystal display panel 11 turns ON 2nd switching elements 12 in order with a gate control signal S2 and plural source lines 2 can be driven in order with desired intermediate level voltages which are divided with time and sent out of one output 19 of the circuit 18.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a method for driving a liquid crystal display panel, and more specifically, a liquid crystal display panel used as a color display in office automation equipment such as a personal computer or word processor, or a television. The present invention relates to a method of driving and controlling a motor.

[Conventional technology]

There are two types of liquid crystal display panels used in personal computers, office automation equipment such as word processors, televisions, and the like: simple matrix type and active matrix type. The former simple matrix method has the advantage that the manufacturing cost of the liquid crystal display panel is low, but has the disadvantage that the response speed and visibility characteristics are low and the image quality is poor. On the other hand, the latter active matrix method has the drawback that the manufacturing cost of the liquid crystal display panel is high, but on the other hand, the response speed and visibility characteristics are very good, the image quality is excellent, and it is particularly suitable for color display with gradation. In recent years, there has been a trend towards multi-color display, and in this respect the active matrix method is often used.

In this active matrix method, each pixel of the liquid crystal display panel has a control element such as a transistor or a diode, and when a transistor is used as the control element, a T P T (
It has a structure in which a thin film transistor (Thin Film Transistor) is formed.

This TPT active matrix type liquid crystal display panel (1) has source lines (2), which are X electrodes extending in the Y direction and arranged in large numbers along the X direction, as shown in FIGS. 4 and 5, for example. (2)... and gate lines (3) (3)..., which are Y electrodes extending in the X direction and arranged in large numbers along the Y direction, are arranged in a matrix on the surface of a liquid crystal (not shown). It has a structure in which a bank light is arranged on the back side of the liquid crystal, and the intersection of the source line (2) and gate line (3) becomes the pixel (4), and this image!
A transistor (5) and a capacitor (6) are connected to (4). In the pixel (4), the transistor (5) is ONL, and the light transmittance of the liquid crystal changes, and the capacitor (6) is charged.
) is turned off, the state of light transmission in the liquid crystal due to the charging voltage of the capacitor (6) is maintained until the transistor (5) is turned on next time. By such a method, the image quality of the image on the liquid crystal display panel (1) is improved. As described above, the driver IC (7) which applies a predetermined voltage according to data to the source line (2) is connected to the source line (2).

[Problem to be solved by the invention]

As mentioned above, conventionally, a driver IC (
One output (8) of 7) is connected to one source line (2) in a one-to-one correspondence. Therefore, for example, R
640. per GB. That is, 640x3 source lines (
When trying to connect a driver IC (7) with 120 outputs (8) to each source line (2) of a color display panel (1) for OA equipment with 2), a total of 16 driver ICs (7) are connected. ) is required.

By the way, when performing color display with gradation, the ON/OF applied to the transistor (5) of each pixel (4)
If a plurality of intermediate level voltages are arbitrarily set among the F voltages, for example, eight gradations are set for each RGB, a total of 512 colors can be displayed. In recent years, as color displays have become more multi-colored, increasing the number of gradations has made it difficult to control the voltage applied to the transistor (5), which has resulted in the size of the driver IC (7) increasing. There is a problem in that as the size of the driver IC (7) increases, the driver IC (7) itself also becomes expensive, leading to an increase in the cost of the liquid crystal display panel.

The present invention was proposed in view of the above problems, and its purpose is to provide a method for driving a liquid crystal display panel that can realize multicolor display with an inexpensive liquid crystal display panel. be.

[Means to solve the problem]

Technical means for achieving the above object of the present invention is to connect source lines extending in the Y direction of an active matrix liquid crystal panel and arranged in large numbers in the X direction to a driver I.
In this method, a first switching element is provided for each data line of a driver IC having a plurality of data lines, and a second switching element is provided for each source line of the liquid crystal display panel, and the driver IC has a plurality of data lines. 1°
Connect one output of the driver IC to the data line and multiple source lines of the liquid crystal display panel corresponding to the first output of the driver IC.
By synchronizing each of the switching elements with the second switching elements of the liquid crystal display panel and sequentially turning them ON and OFF, the source data from the data line is time-divided and the source data corresponding to the data line is transferred from one output of the driver IC to the source data corresponding to the data line. The idea was to supply it to the line.

[Operation] In the method of the present invention, the first switching element of the driver IC and the second switching element of the liquid crystal display panel are synchronized to time-divide the source data from the data line of the driver IC. The source data can be supplied to a plurality of source lines from one output of the driver IC, and the driver ICs connected to all the source lines of the liquid crystal display panel can be made more compact or the number of driver ICs can be reduced.

〔Example〕

A first embodiment of the method for driving a liquid crystal display panel according to the present invention will be described below.
This will be explained with reference to FIGS. 3 to 3.

The liquid crystal display panel (11) of the present invention shown in FIGS.
) is the conventional liquid crystal display panel (
It has substantially the same structure as 1), and the same or equivalent parts are given the same reference numerals and redundant explanation will be omitted. The difference between the liquid crystal display panel (11) of the present invention and the conventional one is that each source line (2) (
2) A second switching element (12) on the input side of...
(12)... is provided. This second switching element (12) (12)... is connected to the source line (2) (2)... and the gate line (3) (3).
. . . Similarly to the transistors (5) (5) . . . provided in each picture @ (4) (4) . . . where the . . .

Next, the source line (2) of the liquid crystal display panel (11)
(2) As shown in FIGS. 1 and 2, the driver IC (13) of the present invention applies a predetermined voltage to a plurality of
For example, three data lines (14) corresponding to RGB
(14) It has (14). Each data line (
14) (14) (14) enables 512-color display with 8 gradations by transmitting 3-bit source data. Incidentally, the data lines (14) do not necessarily have to correspond to RGB, and it is also possible to have two or four or more data lines. In addition, when performing color display with 166 gradations and 4096 colors, each data line (14) will transmit 4-bit source data, and the data line (14) will be transmitted based on the gradation setting for color display. It is only necessary to set the number of bits for each of the above data lines (14).
(14) (14) has a flip-flop circuit (15
) (15) (15) and latch circuit (16)
(16) (16) is connected. This flip-flop circuit (15) (15) (15) is a circuit that stores 1-bit source data, and the latch circuit (
16) (16) Since (16) is also a circuit that holds 1-bit source data for a predetermined period of time, the 3-bit data line (14) (14) (
14) is a flip-flop circuit (15) (15)
(15) and latch circuit (16) (16)
(16), each having three pieces. In the present invention, the first switching element (17) (17) (17) is connected to the output of the latch circuit (16) (16) (16), and the first switching element (17) (17)
(17) to connect the output circuit (18). still,
Three first switching elements (17) are provided for each data line (14) depending on the number of bits.

In the above output circuit (18), 3 of the data lines (14)
One output (19) is provided for human power, and this one output (
19) to the three source lines (2) (2) (2) of the liquid crystal display panel (11) and the second switching element (12).
(12) Common connection via (12). This output circuit (18) converts the digital input of 3-bit source data into analog and outputs a voltage at a desired level.As shown in Figure 3, in color display with 8 gradations, the transistor (5 ) (5) ..., eight switching circuits (20) (20
)..., each switching circuit (20)
(20) 1st to 8th intermediate level voltage ■1 to V
Enter 8. Each switching circuit (20) (20)
. . are connected in common and become one output (19) of the output circuit (18). Incidentally, when the output circuit (18) operates, the selection of which switching circuit (20), (20), etc. is performed is performed by a decoder circuit (not shown).

Next, the operation of the liquid crystal display panel (11) and driver IC (13) having the above configuration will be explained.

First, in the driver IC (13), each data line (1
4) (14) The 3-bit source data in (14) is sent to the flip-flop circuit (15) (15) (
15) and is stored in the launch circuit (16) (1
6) It is held for a predetermined time in (16). The source data output from this latch circuit (16) (16) (16) is transmitted to the first switching element (17) (17
) (17) to the output circuit (18). At this time, the first switching element (17) (
17) Turn on (17) sequentially by applying a gate control signal (Sl). This allows the output circuit (18) to select the desired switching circuit (20) based on the source data on the data lines (14) (14) (14).
(20) . . . are sequentially turned on to sequentially output a desired voltage among the first to eighth intermediate level voltages V1 to V8.

In the liquid crystal display panel (11), the driver IC
(13) First switching element (17) (17
) (17), the second switching element (
12) (12) (12) as gate control signal (S
2), one output of the output circuit (18) (
Desired first to eighth intermediate level voltages ■1 to V8 sent out in a time-division manner from 19) to a predetermined source line (2) (
2) Sequentially supply to (2).

By the way, in the driver IC (13) of the present invention, a plurality of, for example, three transistors (5) (5) (5) of the source lines (2) (2) (2) are driven by one output circuit (18). be able to. In contrast, conventional driver ICs
In (7), in order to drive the transistors (5) (5) (5) of the three source lines (2) (2) (2), 3
requires two output circuits. In general, the output circuit of a driver IC occupies most of the area of the circuit configuration built into the driver IC, so reducing the number of output circuits makes it easier to significantly downsize the driver IC (13). Alternatively, the driver IC (1) connected to all source lines (2) (2)... of the liquid crystal display panel (11)
3) It is also possible to reduce the number of devices themselves.

〔Effect of the invention〕

According to the method of the present invention, the first switching element of the driver IC and the second switching element of the liquid crystal display panel are synchronized, and source data is time-divided from one output of the driver IC and supplied to a plurality of source lines. By doing so, the driver IC can be made more compact or the number of valences can be reduced, making it possible to realize multicolor display with an inexpensive liquid crystal display panel.

[Brief explanation of drawings]

1 to 3 are for explaining an embodiment of the method of the present invention. FIG. 1 is a partial circuit block diagram showing a part of a liquid crystal display panel and a driver IC, and FIG. 2 is a partial circuit block diagram of a liquid crystal display panel and a part of a driver IC. FIG. 3 is a plan view showing the source line, gate line, and driver rc, and FIG. 3 is a circuit block diagram showing the inside of the output circuit of the driver IC shown in FIG. 4 and 5 are for explaining a conventional method of driving a liquid crystal display panel. FIG. 4 is a plan view showing the source line, gate line, and driver IC of the liquid crystal display panel, and FIG. 5 is an enlarged plan view of a main part showing a pixel of the liquid crystal display panel of FIG. 4. FIG. (2) - Source line, (11) - Liquid crystal display panel, (12) - Second switching element, (13)
-Driver IC. (14) - data line, (17) - first switching element, (19) - 4 outputs. 13゛ Renal cyst/IC patent applicant: Kansai NEC Co., Ltd.
Rinto Gangwon Sho Go 6th 2nd
Figure 3 Figure 4 Figure 5

Claims (1)

[Claims] (1) A method in which a driver IC drives and controls a large number of source lines extending in the Y direction and arranged in the X direction of an active matrix liquid crystal panel. one switching element is provided, and a second switching element is provided for each source line of the liquid crystal display panel, one output of the driver IC is connected to a plurality of source lines of the liquid crystal display panel corresponding to the data line, and the driver IC By synchronizing each of the first switching elements of the liquid crystal display panel with each of the second switching elements of the liquid crystal display panel and turning them ON and OFF sequentially, the source data from the data line is time-divided and transferred from one output of the driver IC to the data line and the second switching element of the liquid crystal display panel. A method for driving a liquid crystal display panel, characterized in that the supply is supplied to a corresponding source line.