KR100589786B1 - Method for wiring for panel drive - Google Patents

Abstract

The present invention proposes a new method of driving a PM (Positive Matrix) OLED, and it is difficult to drive a single chip due to an increase in panel size and power increase due to an increase in scan line, which is accompanied by high resolution, and an increase in data line. As a countermeasure, to solve the problem of using multiple ICs to drive the panel, a new IC is used to reduce the resistance of the scan line while driving the panel and driving the pixel, thereby reducing the consumption of the entire panel. The present invention relates to a wiring method for driving a panel which reduces power and reduces data distortion by reducing delay of data lines.

Panel, scan line, data line, resolution, luminance

Description

Wiring method for panel drive {METHOD FOR WIRING FOR PANEL DRIVE}             

1 is a diagram illustrating a scan line wiring of a dual scan method for driving a conventional panel.

2 is a view for explaining a wiring method for driving a panel according to the present invention;

3 is a diagram for explaining a distortion phenomenon of current applied to one pixel of a panel.

<Description of the symbols for the main parts of the drawings>

10 panel 12 data line

14 scan line 16 PAD

20: IC 22: common terminal part

24: first terminal portion 26: second terminal portion

The present invention relates to a wiring method for driving a panel. More particularly, the present invention proposes a new method of driving an OLED of a positive matrix (PM) method. As the size of the panel increases and the scan line accompanying the high resolution increases, In order to solve the problem of one chip driving due to the increase of power and the increase of data line, and to solve the problem of using a plurality of ICs for driving the panel, a panel driving and a pixel driving are performed by using a new IC. The present invention relates to a wiring method for driving a panel, which reduces the resistance of the circuit board, thereby reducing power consumption required for driving the entire panel, and reduces data distortion.

In general, the PM type OLED panel driving method is increasing power consumption due to the increase of the panel size, the increase of the resistance of the scan line and the resulting voltage drop as the panel resolution increases.

To prevent this, currently, the panel is divided into a data line and a scan line, and a dual scan method using a plurality of ICs to separate the panel into two zones is used.

1 is a diagram illustrating a scan line wiring of a dual scan method for driving a conventional panel.

As shown in FIG. 1, a dual scan driving method is conventionally used as a method for reducing the increase in the resistance of a scan line by 1/2 due to an increase in panel size, which is a data extending from the top to the bottom of the panel. The line is separated at the center of the panel. The data of one frame is divided in half and stored in two memories, and the data stored in each memory is supplied from the top of the panel to the center of the panel and from the bottom of the panel to the center of the panel. Alternatively, because scanning with a slight time difference, as described above, not only can the load on the data line be reduced to 1/2 but also the scanning signal can be applied to the scan line for a sufficient time.

However, in the case of panel driving ICs currently applied, 96 × 64, 96 × 96 or even 128 × 128 can be driven by a single chip. Increasing power consumption and luminance deterioration according to the increase is a problem.

Accordingly, there are many attempts to reduce power consumption by driving 3 or 4 ICs using 3 PADs to drive PM OLEDs with a resolution of 128 × 128 or higher.

As a result, the number of ICs used increases, which is a major factor that increases the manufacturing cost.

In addition, in the structure using a conventional IC and driving with multiple PADs, power consumption is required to produce the required luminance due to uneven brightness and voltage drop due to the difference between the resistance of the scan line and the resistance of the center region. There is an increasing problem.

The present invention was devised to solve the above-mentioned problems of the prior art, and the present invention is a dual scan driving method using 3PAD and one IC using a new IC instead of the current PAD and IC arrangement method which is a problem at high resolution. By reducing the resistance in the scan line by directly connecting the IC and the scan line, the power consumption is reduced by reducing the luminance deviation and the voltage drop caused by the resistance, and by separating both the gate and the source, RC of one scan line or data line itself Provides wiring method for panel driving to reduce current and flow current per pixel, and double scan or quadruple scan method to secure enough time to apply current to increase pixel light emitting effect. Its purpose is.

In order to achieve the above object, the present invention provides a panel including an array of a plurality of self-emissive elements, wherein the panel and the first terminal part, a second terminal part, and a scan signal are applied to apply a data signal for driving the panel. The wiring is connected to an IC having a common terminal part, and the data line group formed at the lower half of the panel is connected to the first terminal part, and the data line group formed at the upper half of the panel is connected to the second terminal part. The scan line group formed in the horizontal direction of the panel is connected to the common terminal unit.

In the present invention, the panel separates the source data signal to separate the upper half and the lower half of the panel so as to reduce the voltage drop due to the RC component to connect to the first terminal portion and the second terminal portion of the IC, respectively, characterized in that the wiring do.

In addition, the panel is separated by the gate (Gate) signal, characterized in that the wiring is connected to the common terminal of the IC by separating the panel so that the voltage drop caused by the RC component is reduced.

In addition, the panel is characterized in that the data line and the scan line group is separated by 2n each and wired.

As described above, the present invention applies a dual scan driving method using 3PAD and one IC, and reduces the resistance in the scan line by directly connecting the IC and the scan line, thereby reducing power consumption by reducing the luminance deviation and the voltage drop caused by the resistance. By separating both the gate and the source, the RC component of one scan line or the data line itself is reduced to secure sufficient time to apply the current to each pixel, thereby enhancing the light emission effect of the pixel.

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

FIG. 2 is a diagram for describing a wiring method for driving a panel according to the present invention, and FIG. 3 is a diagram for explaining a distortion phenomenon of current applied to one pixel of a panel.

First, in driving a panel, when a color data line and driving data are applied to one pixel of the panel, distortion is generated in the current applied to the pixel as shown in FIG. 3 unless sufficient time is secured.

This is an inevitable structural problem in passive OLED driving, which exceeds V _{TH due} to the RC component of the data line and the scan line itself, but does not flow enough current required for the pixel to emit light.

If the resolution of the panel is low, a single scan is enough time, but if the resolution is increased and the scan lines and data lines are increased, the scan time per line is reduced, so that the pixels do not emit light properly. .

The present invention is not a simple way to solve this problem by simply increasing the number of scan lines and pads or the IC, but to drive the pixel properly using the proposed new structure of the IC while driving the panel.

According to the present invention, as shown in FIG. 2, in the panel 10 having an array of a plurality of self-light emitting devices, the first terminal portion 24 and the first terminal part 24 for applying a data signal for driving the panel 10 and the panel are provided. The wiring is connected to the IC 20 having the two terminal unit 26 and the common terminal unit 22 for applying the scan signal, and the data line group formed at the lower half of the panel 10 is connected to the first terminal unit 24. The data line group formed on the upper half of the panel 10 is connected to the second terminal part 26 and wired, and the scan line group formed in the horizontal direction of the panel 10 is connected to the common terminal part 22. Wire it.

In addition, the panel 10 separates the upper half and the lower half of the panel 10 so as to reduce the voltage drop caused by the RC component by separating the source data signal, thereby separating the first terminal portion 24 and the first terminal portion 24 of the IC 20. The two terminals 26 are connected to each other for wiring.

In addition, the panel 10 separates the gate signal and separates the panel so as to reduce the voltage drop caused by the RC component and connects the wiring to the common terminal 22 of the IC 20.

In addition, the panel 10 may separate and wire the data line 12 and the scan line 14 groups in 2n multiples.

The amount of current applied to one scan line instantaneously to obtain the brightness of the entire panel is the number of I * scanlines. Where I is the brightness of the current when only one line is flowing.

The double scan drive doubles the flow time of the current, eliminating the need to sharply increase the instantaneous current required to achieve the required brightness, thereby increasing the lifetime of the OLED device and increasing the panel usage time.

That is, in the present invention, when the panel has a high resolution, the common terminal unit 22 of the IC is divided into two parts, and the second terminal unit 26 controls the color data of the upper part. By controlling the lower color data, the image appears on the screen in accordance with the power supply supplied by the common terminal unit 22.

Then, the resistance in the scan line is reduced to reduce the power consumption through the luminance deviation and the voltage drop caused by the resistance, and the RC component of one scan line or the data line itself is reduced by the separation of the gate and source data and flows pixel by pixel. The current application time is secured enough to increase the light emission effect of the pixel.

As described above, the present invention applies a dual scan driving method using 3PAD and one IC, and directly reduces the resistance in the scan line by directly connecting the IC and the scan line, thereby reducing power consumption by reducing the luminance deviation and voltage drop caused by the resistance. By reducing both the gate and the source, and reducing the RC component of one scan line or the data line itself, it is possible to secure sufficient time to apply the current flowing through each pixel to increase the light emission effect of the pixel, thereby improving the characteristics of the panel. have.

In addition, the present invention provides three pads in a dual scan method using at least two PADs and two ICs or a plurality of ICs to drive the panel in order to maintain the image quality of the panel when the resolution of the panel increases. Driving by a single IC has the advantage of reducing the cost of labor and use IC.

Claims (4)

In a panel consisting of an array of a plurality of self-emissive elements, Wiring is connected to an IC having the first terminal portion for applying a data signal, the second terminal portion for applying a data signal, and a common terminal portion for applying a scan signal for driving the panel and the panel. The data line group formed at the lower half of the panel is connected to the first terminal part for wiring, and the data line group formed at the upper half of the panel is connected to the second terminal part for wiring. The scan line group formed in the horizontal direction of the panel is common. A wiring method for driving a panel, characterized in that the wiring is connected to the terminal unit. The method of claim 1, The panel separates the source data signal and separates the upper half and the lower half of the panel so as to reduce the voltage drop caused by the RC component. The panel is connected to the first terminal part and the second terminal part of the IC for wiring. Wiring way for you. The method of claim 1, The panel is a wiring method for driving the panel, characterized in that to separate the gate (Gate) signal to reduce the voltage drop due to the RC component is connected to the common terminal of the IC and wiring. The method of claim 1, The panel is a wiring method for driving the panel, characterized in that for each of the data line and the scan line group separated by 2n wiring.

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