KR20040089256A - Method and apparatus for achieving active matrix oled display devices with uniform luminance - Google Patents

Abstract

PURPOSE: An apparatus for achieving an active matrix OLED display device of uniform luminance and a method thereof are provided to improve image uniformity of the display device by acting as a compensation unit having an automatic control function. CONSTITUTION: The apparatus achieves uniform luminance of an active matrix OLED comprising a number of pixel devices. According to each pixel device, a switch unit(1) has two input ports and output ports connected to a data line(D) and a scan line(S) respectively. A storing unit(4) has one port connected to a supply line(P) and another port connected to the output port of the switch unit. A compensation unit(3) has to input ports connected to the supply line and the output port of the switch unit respectively. A driver unit(2) has an input port connected to the output port of the compensation unit, and an input port connected to a connection part of the output port of the switch unit and one input port of the compensation unit, and an output port. And an OLED(5) has an input port connected to the output port of the driver unit and a grounded output port.

Description

TECHNICAL AND APPARATUS FOR ACHIEVING ACTIVE MATRIX OLED DISPLAY DEVICES WITH UNIFORM LUMINANCE

The present invention relates to a method and apparatus for achieving uniform brightness of an active matrix OLED display device, and more particularly, to a method and apparatus for automatically adjusting a loading characteristic curve according to an input voltage signal.

Currently known thin film transistor liquid crystal display (TFT LCD) technology can be classified into amorphous silicon TFT (a-Si TFT) and poly-Si TFT. A-Si TFT, which has been technically developed and is the mainstream of LCD products, is commonly referred to as TFT-LCD. The main difference between low pressure poly-Si TFTs and a-Si TFTs is that LTPS transistors are fabricated in order to transform the amorphous silicon thin film into a polysilicon thin film so that the silicon structure of the LTPS is more aligned than the a-Si TFT. While laser annealing is required. This can increase the electron mobility to 200 cm ² / V-sec. LTPS technology allows the device to be made smaller. The area of the entire TFT element can be reduced by more than 50%. The aperture ratio can also be improved. Compared to a-Si TFT-LCDs of the same dimensions, LTPS TFTs have high resolution and low power consumption. LTPS TFTs also offer power savings, high light intensity, finer screens, thinner and lighter, fewer connection points (a-Si TFTs have more than 3842 connection points, while less than 200 connection points Increase).

However, in the manufacturing process of LTPS, the thin film transistor must go through a laser annealing operation causing a change in the threshold voltage and mobility of the TFT. Therefore, the characteristics are different for each TFT element. When the driver system uses an analog modulation method to achieve gray scale of the image, the different characteristics of the TFTs caused by the laser annealing operation may cause OLEDs of different pixels to emit light of different intensities even if the same voltage signal is programmed. Thus, an OLED display with non-uniform brightness can be generated. This phenomenon can cause OLED panels to display erroneous gray scale images, which significantly impairs image uniformity.

US Pat. No. 5,684,365, entitled "TFT Display Panel Using Organic Electroluminescent Media," discloses a pixel circuit technology consisting of two TFTs and one capacitor 2T1C. When the pixel device scans the image data, the switch unit is conductive and the image data is supplied to the switch unit via the data line. After scanning by the scan line, the data is stored in the storage unit (ie the reservoir unit is charged after the switch unit becomes conductive). The voltage difference of the reservoir unit supplies Vsg to the driver unit so that the driver unit can output current to the OLED element. The luminous intensity generated by the OLED device is directly proportional to the current flowing through the OLED device. However, when the characteristics of the driver unit of the pixel device are changed due to the manufacturing process, the light generated by the OLED element is not constant, thereby impairing image uniformity.

US Pat. No. 6,229,506, entitled "Active Matrix Light Emitting Diode Pixel Structure and Manufacturing Method thereof," discloses a 4T2C pixel circuit. An auto-zero mechanism is provided here to compensate for variations in transistor threshold voltages. When data is scanned, the drive sequence is divided into an auto-zero state, a load data state and a light emitting state. However, in addition to data lines, scan lines, and supply lines, pixel devices require auto-zero control lines and light emission control lines. This causes a decrease in the openings.

Reference is made to the publication published by Electronic Research & Service Organization, Industrial Technology Research Institute (ROC), entitled "Pixel Devices for Improving Image Uniformity of Active Matrix OLEDs" (IDW, 01), here 2T1C + R. A pixel device is provided, which includes a passive resistor for adjusting the Vsg of the TFT of the driver unit to compensate for the characteristic change, but it is difficult to include the passive resistor. Since the voltage drop of the passive resistor is large, a large power supply is required to provide a voltage.

See “Amorphous TFT Active Matrix OLED Display Device” published by Jerzy Kanicki (University of Michigan, U.S.A). Here, a pixel device composed of 3T1C is provided, and an active load for adjusting the Vsd of the TFT of the driver unit is used to compensate for the characteristic change of the TFT. However, when the TFT has a large output amount of current, the voltage drop of the active load is large. Therefore, a large power supply is required to provide a voltage.

Therefore, the main object of the present invention is to solve the above-mentioned disadvantages. The present invention relates to a method and apparatus for achieving uniform brightness of an active matrix OLED display device having a pixel device comprising a 3T1C structure. One of the TFTs functions as a compensation unit having an auto-adjustment function to compensate for characteristic changes in the threshold voltage and mobility of the driver unit TFT, thereby improving image uniformity of the display device.

In order to achieve the above object, a display device according to the method and apparatus of the present invention includes a plurality of pixel devices. Each pixel device includes a driver unit for driving the OLED for light emission and a compensation unit for adjusting the Vsg of the driver unit to compensate for the characteristic change of the driver unit so that the image of the display device is less affected by the characteristic change of the driver unit. Receive.

Further objects, features and advantages of the invention in addition to those described above are more clearly described in the following detailed description described with reference to the accompanying drawings.

1 is a schematic circuit diagram of the present invention.

2 is a schematic diagram of the current-voltage relationship of the compensation unit of the present invention.

3 is a schematic diagram of the current-voltage relationship of the driver unit when Vth is small.

4 is a schematic diagram of the current-voltage relationship of the driver unit when Vth is large.

5 is a schematic diagram of the current-voltage relationship of the compensation unit of the invention under different input voltage signals.

Explanation of symbols on the main parts of the drawings

1: switch unit 2: driver unit

3: reward unit 4: storage unit

5: OLED S: Scan Line

D: data line P: supply line

The invention refers to the circuit diagram of FIG. 1. According to the method and apparatus of the invention, the active matrix OLED display device comprises a plurality of pixel devices. Each pixel device includes a driver unit for driving the OLED for light emission and a compensation unit for adjusting the Vsg of the driver unit to compensate for the characteristic change of the driver unit, so that the image uniformity of the display device affects the characteristic variation of the driver unit. Receive less.

In the method described above, the pixel circuit 10 of the invention consists of a switch unit 1, a driver unit 2, a compensation unit 3, a storage unit 4 and an OLED 5.

The switch unit 1 may be a thin film transistor TFT having two inputs 11 and 12 connected to the scan line S and the data line D, respectively.

The driver unit 2 is connected to one input 21 connected to the output 33 of the compensation unit 3 and the junction of the output 13 of the switch unit 1 and the input 32 of the compensation unit 3. It can be a TFT with another input 21 connected.

The compensation unit 3 can be a TFT having one input 31 connected to the supply line P and another input 32 connected to the output end 13 of the switch unit 1.

The storage unit 4 comprises a capacitor having one end connected to the supply line P and the other end connected to the output 13 of the switch unit 1.

The OLED 5 has an input and a grounded output end connected to the output end 23 of the driver unit 2.

When the scan line S is selected, the switch unit 1 may be turned on. The data line D is connected to the storage unit 4 via the switch unit 1, so that the setting data voltage level of the data line D can be stored in the storage unit 4. The driver unit 2 outputs a current so that the OLED 5 emits light. The current flowing through the OLED 5 determines the brightness of the OLED 5.

Reference is made to FIG. 2 for the current-voltage relationship of the compensation unit 3 of the invention. As shown in the figure, when the voltage difference Vc stored in the storage unit 4 is equal to Vdata1, Vsg3 equal to Vdata1 is provided on the compensation unit 3. If the threshold voltage Vth of the driver unit 2 is an average value, the voltage drop Vsd3 for the compensation unit 3 becomes an average value V1. Subtracting Vsd3 for the compensation unit 3 from the voltage difference Vc of the storage unit 4 becomes Vsg2 for the driver unit 2. Thus, the driver unit 2 can output the average current I1.

When the Vth is small, the current-voltage relationship of the driver unit 2 is referred to FIG. 3. As shown in the figure, when the threshold voltage of the driver unit 2 is small and Vth-AVth is the same, the driver unit 2 passes a large current output through the compensation unit 3 to be V2 to increase Vsd3. Have Therefore, Vsg2 of the driver unit 2 becomes small. As a result, the output current I2 of the driver unit 2 does not exceed the average value I1 so as not to be too large so that the image uniformity of the display device is less affected by the characteristic change in the threshold voltage of the driver unit 2.

When Vth is large, the current-voltage relationship of the driver unit 2 is referred to FIG. 4. As shown in the figure, when the threshold voltage of the driver unit 2 is large and equal to Vth + AVth, the driver unit 2 passes a small current output through the compensation unit 3 to be V3 to reduce Vsd3. Have Therefore, Vsg2 of the driver unit 2 becomes large. As a result, the output current I3 of the driver unit 2 is not too large at least the average value I1 and the image uniformity of the display device is less affected by the change in the threshold characteristics of the driver unit 2. Based on the above description, when the threshold voltage of the driver unit 2 fluctuates, the fluctuation is compensated by increasing or decreasing the voltage Vsd3 for the compensation unit 2 and the voltage Vsg2 of the driver unit 2. Can be.

The most notable feature of the invention is that the compensation unit 3 can automatically adjust the load characteristic curve according to the input voltage signal (i.e., the voltage difference Vc stored in the storage unit 4) so that the output current is different. To adjust the voltage drop Vsd3 for the compensation unit 3. Thus, when the driver unit 2 outputs a large current, the compensation unit 3 can maintain a low voltage drop occurring between the two ends so that the circuit can provide a low power supply voltage.

Reference is made to FIG. 5 for the current-voltage relationship of the inventive compensation unit according to different input voltage signals. As shown in the figure, when the voltage difference Vc stored in the storage unit 4 is small and equal to Vdata1, Vsg3 (same as Vdata1) of the compensation unit 3 is also small. When the threshold voltage Vth of the driver unit 2 is an average value, the driver unit 2 outputs an average current I1 and Vsd3 of the compensation unit 3 has an average voltage drop V1.

When the voltage difference Vc stored in the storage unit 4 is large and equal to Vdata2, Vsg3 (same as Vdata2) of the compensation unit 3 is also large. When the threshold voltage Vth of the driver unit 2 is an average value, the driver unit 2 outputs an average current I4 and Vsd3 of the compensation unit 3 has an average voltage drop V4.

When the voltage difference Vc stored in the storage unit 4 changes from Vdata1 to Vdata2, when the compensation unit 3 does not automatically adjust the load characteristic curve, the driver unit 2 outputs a large current I4. And the voltage drop Vsd3 of the compensation unit 3 is equal to V5, which is considerably larger than V4. In this condition, a large power supply must be used to provide a voltage such that the storage unit 4 has a voltage difference Vc large enough to maintain a large output current I4.

In summary, the present invention provides the following advantages:

1. The present invention can improve the image uniformity of the OLED display device by using an auto-regulating active load that adjusts the Vsg of the driver unit to compensate for the characteristic change in the threshold voltage and mobility of the TFT.

2. Under different input voltage signal conditions, the compensation unit of the present invention can automatically adjust the load characteristic curve according to the input voltage signal, so as to adjust the voltage drop for the compensation unit when different average output voltages are generated. Thus, even if the driver unit outputs a large current, the compensation unit can maintain a low voltage drop for the two ends. Thus, the pixel device can operate at a low voltage of power supply.

While the preferred embodiments of the present invention have been described for purposes of illustration, modifications and other embodiments of the embodiments disclosed herein will be apparent to those skilled in the art. Accordingly, the appended claims may be practiced in all embodiments without departing from the spirit and scope of the invention.

The pixel device of the present invention includes a driver unit for driving the OLED for emitting light and a compensation unit for adjusting the Vsg of the driver unit to compensate for the characteristic change of the driver unit, so that the image of the display device influences the characteristic change of the driver unit Receive less.

Claims (6)

A device for achieving uniform brightness of an active matrix organic light emitting diode (OLED) consisting of a plurality of pixel devices, each pixel device comprising: A switch unit having two input ends and an output end respectively connected to the data line and the scan line, respectively; A storage unit having one end connected to a supply line and another end connected to an output end of the switch unit; A compensation unit having two input ends each connected to the supply line and an output end of the switch unit; Two input ends consisting of one input end connected to the output end of the compensation unit and another input end connected to the junction of the output end of the switch unit and one input end of the compensation unit, and having an output end Driver unit; And And an OLED having an input end connected to the output end of the driver unit and a grounded output end. The apparatus of claim 1, wherein the switch unit is a thin film transistor. The apparatus of claim 1, wherein the driver unit is a thin film transistor. 2. The apparatus of claim 1, wherein said unit comprises a capacitor. The apparatus of claim 1, wherein the compensation unit is a thin film transistor. A method for achieving uniform brightness of an active matrix organic light emitting diode (OLED) consisting of a plurality of pixel devices, each pixel device comprising a driver unit for driving an OLED for emitting light, the method comprising: Providing a compensation unit for adjusting Vsg of the driver unit; And Compensating for a characteristic change of the driver unit to produce a display device which is less affected by the characteristic change of the driver unit.