KR20030044568A - Method for manufacturing an passive matrix organic electroluminescent panel and display operating system thereof - Google Patents

Abstract

PURPOSE: A method for manufacturing a manual matrix organic electroluminescence panel and a display driving system are provided to improve the duty ratio of a panel by changing a column line and a row line of the panel. CONSTITUTION: A CPU(Central Processing Unit)(70) controls an image in a memory(72). The memory(72) stores image data suitable for a size of an organic electroluminescence panel. A port(74) transmits a control signal required to scan a row line of a panel in the CPU(70). A serial interface(76) transmits video and image data inputted from an external in order to store on the memory(72) and sends them by a column line signal of the panel. A row driver(78) scans the panel. A column driver(80) transmits the image data of the panel.

Description

Method for manufacturing an passive matrix organic electroluminescent panel and display operating system

The present invention relates to a method for fabricating a passive matrix organic EL panel and a display driving system thereof, and more particularly, to a column line and a row line of a panel when fabricating an organic EL panel using a passive matrix. The present invention relates to a method for fabricating a passive matrix organic EL panel and a display driving system thereof, which are related to a method of manufacturing by changing the manufacturing method and a driving system for displaying an image signal on a panel manufactured by the above method.

In order to fabricate an organic EL panel using a passive matrix, it is necessary to form a cathode electrode having a regular linear pattern.In view of the fact that the wet etching process is generally difficult to apply due to the characteristics of the organic EL material, indium tin oxide (ITO) Prior to depositing organic material on the anode electrode, a process of continuously depositing the organic layer and the cathode electrode after the formation of the insulation partition wall using a technique of forming a cathode separation barrier using photo-lithography is performed. Through this, the panel can be manufactured without the formation of a separate cathode pattern.

In the case of an active matrix, since a thin film transistor (TFT) is formed in each pixel, the duty ratio becomes 1, so that the structure of the panel does not need to be changed.

Hereinafter, the prior art will be described in more detail with reference to the accompanying drawings.

1 shows a structural diagram of a conventional organic EL panel.

According to the drawing, the deposition arrangement of the organic EL material of each of the red, green, and blue cells (Cells 2a to 2c) is in the vertical direction, and each of the red, green, and blue cells (2a) arranged in the longitudinal direction is arranged. The column lines 10 for applying the gray scale data value to the second to the second columns are also arranged vertically.

The row lines 30 that apply a scan signal to the pixel 20 formed by pairing each of the red, green, and blue cells 2a to 2c are arranged horizontally.

The image signal may be implemented by applying a scan signal corresponding to the vertical resolution of the raw line 30 and applying grayscale data to the column line 10.

The luminance of the organic EL panel varies with the duty ratio of the panel, and the duty ratio of the panel varies with the number of furnace lines 30 of the panel.

An organic EL panel is more preferable for a panel with a smaller duty ratio.

For example, if the column line is 100 lines and the furnace line is 150 lines, FIG. 1 becomes a panel of 300 (100 each of red, green, and blue) x 150, and the duty ratio of the furnace line is 1/150.

However, the larger the number of row lines, the smaller the duty ratio, so the luminance is reduced, and since many lines need to be scanned, there is a problem of increasing power consumption.

SUMMARY OF THE INVENTION In order to solve the problem, the present invention improves the duty ratio of the panel by changing the column line and the furnace line of the organic EL panel, in which the number of the column lines is generally smaller than the number of the furnace lines, thereby improving luminance and reducing power consumption. The purpose.

1 is a structural diagram of a conventional passive matrix organic EL panel.

2 is a structural diagram of a passive matrix organic EL panel according to the present invention;

3 is a block diagram of a display driving system of a passive matrix organic EL panel according to the present invention;

In order to achieve the above object, the present invention arranges row lines for applying a scan signal to pixels vertically, and red, green, and blue cells with horizontal deposition of organic EL materials on red, green, and blue, respectively. A column line for horizontally applying each grayscale data value is arranged horizontally.

Further, the image implementation in the panel as described above, the CPU for adjusting the image in the memory, the memory for storing the image data according to the size of the organic EL panel, the control signal necessary for scanning the raw line in the CPU transfers Port to transmit externally input video and image data signals to the memory or to transmit them to the column line signal, a column to transfer the image data of the panel and the driver to scan the organic EL panel A display driving system having a driver is used.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a structural diagram of an organic EL panel according to the present invention.

According to the drawing, row lines 50 for applying scan signals to the pixels 40 are arranged vertically, and column lines for applying grayscale data values to the red, green, and blue cells 4a to 4c, respectively. 60 are arranged horizontally.

In addition, since the column lines 60 for applying grayscale data values to the red, green, and blue cells 4a to 4c are arranged horizontally, the organic EL material of each of the red, green, and blue cells 4a to 4c is disposed. The deposition arrangement of is also horizontal.

In order to change the line structure as described above, the column line and the furnace line are designed by changing the column line and the furnace line in the photo-lithography process. What is necessary is just to design horizontally and to deposit an organic EL material.

However, even if the line structure is changed as described above, since the size of each pixel is square, it is not necessary to consider the size change of the entire panel according to the design deformation.

This is because, in FIG. 1, since the lengths a and b are the same, there is no change in size even if the width and length thereof are changed.

For example, if the column line and the furnace line of FIG. 1 are used as it is, FIG. 2 is a panel of 100 × 450 (150 each of red, green, and blue).

Here, if the panel 300 (100 each of red, green, and blue) x 150 of FIG. 1 is compared, the lengths of the number 100 of the furnace lines 100 of FIG. 2 and the number 300 of the column lines of FIG. 1 are the same.

Similarly, the lengths of the number 450 of the column lines of FIG. 2 and the number 150 of the furnace lines of FIG. 1 are the same.

Therefore, the panel of the embodiment according to the present invention, in which the column line and the furnace line of the conventional panel are changed, the number of furnace lines becomes 100 lines without changing the overall size, and the duty ratio of the furnace lines is 1/100, which is more than that of the conventional 1/150. It can be seen that the improvement, and when the panel is driven by dual driving, the duty ratio is further improved to 1/50.

Dual drive means not scanning the whole line but scanning in half when scanning the panel.

In other words, when 100 lines are used, 1 to 50 lines are scanned and 51 to 100 lines are scanned, except that 1 to 50 lines and 51 to 100 lines are simultaneously scanned.

The image implementation of the panel has to use a different method because the input lines of the gradation data signal and the scan signal are changed.

In the image realization, in the conventional panel, image data is transmitted through the column lines of the panel. However, in the panel design according to the present invention, since the column lines are formed in the horizontal direction, the image data is stored in a random access memory (ROM). After saving to Read Only Memory (CPU), a separate process (CPU: Central Processing Unit) must be used to address the image of the panel in memory to implement the image.

Hereinafter, with reference to the drawings will be described in detail.

3 is a block diagram of a display driving system of an organic EL panel according to the present invention.

According to the drawing, the display driving system of the organic EL panel includes a CPU 70 for adjusting the image in the memory 72, a memory 72 for storing image data suitable for the size of the organic EL panel, and the CPU 70. Port 74, which transmits the control signal required to scan the low line of the panel, transmits externally input video and image data signals for storage in the memory 72 or transmits them as column line signals of the panel. A serial interface 76, a row driver 78 for scanning a panel, and a column driver 80 for transferring image data of the panel are provided.

In more detail, the CPU 70 controls image data stored in the memory 72 in time or controls the order in which the image data is output from the memory 72.

The memory 72 uses RAM or ROM, and stores image data according to the design of the present invention in which column lines and row lines are switched.

That is, in the image implementation of the panel, the column driver 80 transfers the image data stored in the memory 72 to the panel through the serial interface 76 according to the control signal of the CPU 70, and the row driver 78. Is executed by receiving a scan signal from the CPU 70 through the port 74 and transmitting it to the panel.

As described above, the fabrication of the organic EL panel according to the present invention is easy to manufacture because the panel is manufactured by changing only the design without changing the process, and the manufactured panel reduces the number of scan lines without changing the size of the entire panel. As a result, the duty ratio is improved.

In addition, the duty ratio is improved, thereby improving luminance and reducing power consumption.

Claims (2)

Row lines vertically arranged to apply scan signals to the pixels, and column lines for applying respective grayscale data values to red, green, and blue cells with horizontal deposition of organic EL materials on red, green, and blue, respectively. A method of fabricating a passive matrix organic EL panel, characterized in that it is arranged horizontally. In an organic EL panel in which row lines for applying scan signals to pixels are arranged vertically, and column lines for applying respective grayscale data values to red, green, and blue cells are arranged horizontally, CPU for adjusting the image in memory, memory for storing image data suitable for the size of the organic EL panel, port for transmitting control signals necessary for scanning the raw line from the CPU, video and image data input from outside A serial interface for transmitting a signal to a memory or transmitting it as the column line signal, a row driver for scanning the organic EL panel, and a column driver for transferring image data of the panel, A passive matrix organic EL panel display drive system, characterized by implementing an image.