JPH01126688A - Driving of color flat panel display - Google Patents

Abstract

PURPOSE: To drive a display device without increasing the number of signal electrodes by first driving respective color display dots of an odd row and next driving those of an even row to display one field and repeating this operation. CONSTITUTION: In this display, plural red, green, and blue color display dots are arranged in a prescribed order on each row, and color display dots of even rows are shifted from those of odd rows by a prescribed pitch, and color display dots of an odd row and those of an even row are combined to display one picture element. Color display dots of an odd row are successively driven to display one field, and those of an even row are next driven to display one field, and this operation is repeated. That is, dots constituting one picture element are not simultaneously displayed but are displayed with one field period between them. Thus, the number of electrodes is reduced.

Description

DETAILED DESCRIPTION OF THE INVENTION "Field of Industrial Application" The present invention relates to a method for driving a color flat panel display used for character display, graphic display, television display, etc. in personal computers, word processors, etc.

BACKGROUND OF THE INVENTION As is well known, various color flat panel displays have been developed to replace conventional color CRT (cathode ray tube) displays. Among these, a color liquid crystal display panel in which a color filter is attached to a liquid crystal display panel has already reached the stage of practical use, as it is incorporated into portable color televisions.

In this type of color liquid crystal display panel, an active matrix drive type in which a switch element is provided for each display dot where a plurality of rows of scanning electrodes and a plurality of columns of signal electrodes intersect is conventionally shown in FIG. It was structured like this.

FIG. 3(a) shows a partial schematic configuration. In this figure, ■ is the lower polarizing plate, and 2 is the lower glass substrate. This glass substrate 2. A plurality of rows of scanning electrodes XI are arranged at regular intervals on the upper surface of the .

Xy,... and each of these scanning electrodes X,,X,,...
A plurality of, for example, square drive electrodes D, arranged at regular intervals along . . . , and each scanning electrode X+, Xt, .
. . . and each drive electrode, D, . . . and a switch element E inserted between each of them.

E, . . . are each formed by a thin film forming technique. As the switch element E, for example, an MIM (M eL
A switch element having a metal-insulator-metal structure is used. Further, reference numeral 3 is an upper glass substrate, on the upper surface of which a polarizing plate 4 is provided, and on the lower surface thereof a color filter layer 5 is provided. In this color filter layer 5, a red filter 5r, a green filter 5g, and a blue filter 5b are arranged in correspondence with each drive electrode, D, .
In addition, the same color filters are arranged diagonally, or R, G, and B are arranged at positions on the vertices of a triangle. Further, when a two-terminal element is used as the switch element E as shown in the figure, a transparent striped signal electrode Yl+ is provided on the lower surface of the glass substrate 3 via a color filter layer 5.
Yt+... is the scanning electrode X + + X t +...
・They are formed at equal intervals in the direction perpendicular to . A liquid crystal layer 6 is sealed between the glass substrate l and the color filter layer 5, and a backlight (as shown in the figure) which is a white light source is arranged below the lower glass substrate 2. ing.

Then, each signal electrode Y,, Y,... and each drive electrode.

D, . . . are facing each other in the liquid crystal portions 6 a, 6 a
, . . . each function as a shutter that controls the amount of transmitted white light emitted from the backlight. As described above, a color liquid crystal panel in which a plurality of red, green, and blue display dots R, G, and B are arranged is constructed.

Here, the equivalent circuit of one color display dot is as shown in FIG. . Then, each scanning electrode X,,X,,...
are sequentially scanned to sequentially write display data in the form of charges from the signal electrodes Yl, Yl, . . . to each liquid crystal portion 6a, 6a, . In this case, the switch element E has a characteristic that a current rapidly flows when the threshold voltage is exceeded, so when writing display data, a voltage equal to or higher than this threshold voltage is applied to equivalently The liquid crystal portion 6a functioning as a capacitor is charged. Thereafter, when the voltage is maintained below the threshold value, the switching element E enters a high resistance state, and the electric charge charged in the liquid crystal portion 6a is maintained as it is. As a result, each liquid crystal portion 6a corresponding to each pixel performs a memory holding operation. In this way,
By driving each liquid crystal portion 6a, 6a+, . . . and controlling the amount of transmitted white light emitted from the backlight, each color filter 5r,
The amount of transmitted light of 5g and 5b is controlled, and a color display is performed. In this case, as shown in FIG. 4, R, G,
The B video signal is sampled sequentially in the order of R, G, and H (for each color display driver), that is, at the timing shown by the arrow in the figure, and based on the signal corresponding to the voltage level of each color video signal obtained. , each color display dot R, G, B
The drive voltages for the liquid crystal portions 6a are sequentially controlled. Figure 5 is a diagram showing the correspondence between color display dots and pixels.
A pixel (see dashed line) is configured.

By the way, in the liquid crystal display panel described above, one pixel is composed of three horizontally adjacent color display dots R, G, and B, so the number of pixels in the horizontal direction on the entire display screen is extremely large compared to the vertical direction. Therefore, there was a problem in that it was not suitable for displaying characters or graphics in personal computers, word processors, etc., which required high resolution in the horizontal direction.

Therefore, a color flat panel display was developed which can provide higher resolution in the horizontal direction than the above-mentioned conventional display (see Japanese Patent Application No. 188020/1986). In this color flat panel display, color display dots R, G, and B are arranged as shown in Figure 6, and one pixel is configured as shown by the broken line in the figure, with scanning electrodes X+, Xt...
..., two each (Xl.

X , ), (X ,,
. . . Y, ', Y, ' . . . are driven according to display data from a personal computer or the like.

"Problems to be Solved by the Invention" By the way, the above-mentioned color flat panel display shown in FIG. , °・
There was a drawback that the number of . . . was twice that of the conventional one shown in FIG.

The present invention has been made in view of the above-mentioned circumstances, and an object of the present invention is to provide a method for driving a color flat panel display that can realize color display using the pixel configuration shown in FIG. 6 without increasing the number of signal electrodes. It is an object.

``Means for Solving the Problems'' The driving method according to the present invention arranges a plurality of color display dots of red, green, and blue in each row in a predetermined order, and also arranges a plurality of color display dots of each color in an odd number row. In a color flat panel display in which each color display dot in a row is arranged at a predetermined pitch and one pixel is displayed by combining each color display dot in an odd numbered row and each color display dot in an even numbered row, each color display dot in an odd numbered row is sequentially driven. The system is characterized in that it displays one field by driving the display dots of each color in even rows, then displays one field by driving the display dots of each color in even-numbered rows, and repeats this operation.

"Operation" Conventionally, each dot constituting one pixel was displayed simultaneously, but according to the present invention, one pixel is displayed by two fields. That is, the dots constituting one pixel are not displayed at the same time, but are displayed at intervals of (1) field period. This allows the number of electrodes to be reduced.

"Embodiments" Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a diagram showing a schematic configuration of a color flat panel display to which a driving method according to an embodiment of the present invention is applied. The difference between what is shown in this figure and what is shown in FIG. 6 is that the signal electrodes are It is the composition. That is, the color flat panel display shown in this figure has, for example, square drive electrodes arranged as shown in FIG. is provided. In addition, on the upper surface of the lower glass substrate, similar to the one shown in FIG. 3, scanning electrodes X,, A switch element is provided to connect the drive electrodes, and signal electrodes Y, Y2, etc. are provided on the lower surface of the upper glass substrate to sequentially connect (short-circuit) the square drive electrodes. There is.

In this case, the leftmost drive electrode of each row is connected to the signal electrode Y+, the second drive electrode from the leftmost end of each row is connected to the signal electrode Y, and so on.

Next, a method of driving the color flat panel described above will be explained. Figure 2 (a) shows R from a personal computer.
(B) is a diagram showing the timing at which each display data of (red), G (green), and B (blue) is sequentially output, and (b) is a diagram showing a sampling pulse for sampling the display data. In addition, (c) is a diagram showing sampled display data, and among this sampled data, the data in the upper row is sequentially applied to the odd-numbered signal electrodes Y, Y3, etc., and the data in the lower row The data of even-numbered signal electrodes Y t ,
It is sequentially applied to Y-... Note that an X mark indicates that sampling is not performed.

Now, when image display starts, the personal computer first displays the pixels P, P... (see FIG. 1) in the first row as shown in FIG. 2 (a). Display data is output sequentially. At this time, the scanning electrode XI is scanned, and in the scanning state, each data shown in FIG.

. . . are sequentially driven. That is, first, the R data and G data of the display data DI are each sampled, and the signal electrodes Y, , Y are each driven based on the sampled data, and then the display data D2 is
The B data of is sampled, and the signal electrode Y is driven based on this sampled data, and then,
G data of display data D3.

The R data is each sampled, and the signal electrodes Y, Y, are driven based on the sampled data,
Thereafter, the same process is repeated, and thereby each color display dot D in the first row is displayed. In FIG. 2(c), electrodes driven by each data are shown with parentheses.

When the display of the color display dots D in the first row described above is completed, next, the pixels P in the second row are displayed from the personal computer.
Display data for displaying is output sequentially. At this time, the scanning electrode X is scanned, and in this scanning state,
Display data is sampled sequentially in the same way as above,
Based on this sampled data, the signal electrodes Y + , Y t , . . . are sequentially driven in the same manner as described above. As a result, the color display dot D in the third row is displayed.

Thereafter, the color display dots D on the 5th line, 7th line, etc. are sequentially displayed in the same manner. When the display of the bottom row among the odd-numbered rows is completed, the personal computer sequentially outputs the display data of the pixels P in the first row again. At this time, the scanning electrode X is scanned, and the second row of color display dots D is displayed in the same manner as described above. Next, from the personal computer, the second row pixel P
When the display data of is output, the scanning electrode X4 is scanned, and the fourth row of color display dots D is displayed.
Even-numbered rows of color display dots are displayed one after another. Then, when the display of the even numbered rows is completed, the displaying of the odd numbered rows is performed again, and this process is repeated thereafter.

In this manner, in the above embodiment, display is performed by repeating odd field scanning and even field scanning, and as a result, one pixel P is displayed by scanning two fields. Therefore, in the case of images that change quickly, there is a risk of "shaking" in the display.
In character display or graphic display on personal computers, word processors, etc.
Images and characters rarely change at high speed, so the above-mentioned "blurring" problem does not occur.

In the above-mentioned embodiments, the case where the present invention is applied to a liquid crystal display panel has been described as an example, but the present invention can of course be applied to display panels other than liquid crystal.

Furthermore, the driving method according to the above embodiment and the conventional driving method shown in FIG. 5 (a method in which one pixel is driven as three horizontal dots)
You may also be able to selectively use both. In this way, when displaying on a television screen, the display is performed using the driving method shown in FIG. 5, and when displaying characters on a personal computer terminal, high-resolution display can be performed using the driving method of the above embodiment. becomes possible.

Further, when the number of X electrodes is approximately equal to the number of scanning lines of a television, it is also possible to perform a television display by using the driving method according to the present invention in correspondence with the incremental scan of the television.

"Effects of the Invention" As explained above, in the driving method according to the present invention, the signal electrodes (Y electrodes) that drive dots in odd rows are different from the signal electrodes (Y electrodes) that drive dots in even rows, as shown in FIG. As shown in Figure 1, the dots in the odd rows and the dots in the even rows can be driven by the same signal electrode, thus reducing the number of signal electrodes by half compared to the conventional method. It can be done. As a result, it is possible to reduce the circuit cost and reduce the number of connection points compared to the conventional method, thereby improving reliability.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing the electrode configuration of a color liquid crystal panel to which a driving method according to an embodiment of the present invention is applied, FIG. 2 is a timing diagram for explaining the driving method according to the embodiment, and FIG. ) is a perspective view showing a partial schematic configuration of a color liquid crystal panel using an active matrix drive method using nonlinear elements, FIG. 3(b) is a diagram showing an equivalent circuit for one display dot of the liquid crystal display panel, and FIG. This figure is a diagram for explaining a driving method when displaying a color display image using the same color liquid crystal panel, and FIGS. 5 and 6 are diagrams showing the electrode structure of a conventional color liquid crystal panel. D...Color display dot (drive electrode), P...
... Pixel, Xl, X t X 3... Scanning electrode, Y 3. Yt, Ys...Signal electrode. Applicant Alps Electric Co., Ltd. Representative Kataoka Kataoka Figure 1 Figure 2 + c111I+l-+- x x x -N Gin -m- x x x

Claims (1)

[Claims] A plurality of color display dots of red, green, and blue are arranged in each row in a predetermined order, and each color display dot of an even number row is shifted by a predetermined pitch from each color display dot of an odd number row. In a color flat panel display that displays one pixel by combining display dots and each color display dot in even-numbered rows, each color display dot in odd-numbered rows is sequentially driven to display one field, and then each color display dot in even-numbered rows is driven. 1. A method for driving a color flat panel display, characterized by displaying one field by displaying one field, and repeating this operation.