KR20020089923A - Driving circuit of organic electro luminescence display element - Google Patents

Abstract

PURPOSE: A driver circuit of an organic electro-luminescence display device is provided to improve a luminescent operating speed of a corresponding luminescent body by reducing a rising time of the corresponding luminescent body. CONSTITUTION: A scan driver is formed with a scan voltage portion(21) for applying 0 Volt to scan lines for displaying images and a supply voltage to the remaining scan lines, a standby scan voltage portion(24) for applying a standby voltage during a blanking period, a multiplexer(25) for outputting one of operation standby voltages to corresponding scan lines, and a scan voltage control portion(26) for controlling a voltage selection operation of the multiplexer(25). A data driver is formed with a data voltage portion for applying the supply voltage to data lines for displaying images and 0 Volt to the remaining data lines, a standby data voltage portion for applying the standby voltage to plural data lines during the blanking period, a multiplexer for outputting selectively one of the voltage of the data voltage portion and the voltage of the standby data voltage portion to a corresponding data line, and a data voltage control portion for controlling the voltage selection operation of the multiplexer.

Description

Driving circuit of organic electroluminescent display element

The present invention relates to a driving circuit of an organic light emitting display device for displaying an image on a display panel.

In the conventional data driving method applied to the organic electroluminescent display device, when a constant potential difference occurs between the data line and the scan line of the corresponding unit light emitter, the pixel starts to emit light, and the gray level of the emitting pixel is determined by the current flowing through the pixel. That is, the amount is adjusted according to the current application time flowing in the unit light emitting body according to the constant potential difference.

A data driving circuit diagram of a general organic electroluminescent display device for such a data driving method has a matrix structure in which a plurality of unit light emitters 60 are arranged between a plurality of data lines 50 and a plurality of scan lines 40 as shown in FIG. 1. And a display driver 10 and a data driver 30 for applying data driving signals and scan signals to the plurality of data lines 50 and the plurality of scan lines 40, respectively. do.

The data driving circuit configured as described above grounds the switch of the scan driver connected to the scan line 40 of the unit light emitter so that the zero potential is applied to the scan line 40.

For each of the remaining scan lines to which zero potential is not applied, a power supply potential is applied to each scan line by connecting a switch connected to each scan line to a power source.

Then, the zero potential is applied to the scan line, and the potential connected to the constant current source is connected to a switch connected to the data line to the data line of the unit light-emitting body on which the image is displayed.

The zero potential is applied to the data line of the unit light emitter in which the zero potential is applied to the scan line by which the image connected to the data line is grounded.

Then, among the unit light emitters having zero potential applied to the scan line, the corresponding potential is applied to the data line, so that only the unit light emitters with a voltage higher than the threshold voltage are emitted. Display an arbitrary image on the corresponding scan line to which is applied.

Therefore, after the image is displayed on the corresponding scan line, the entire image is displayed on the display panel by repeatedly performing the above method on the next scan line.

According to the driving method of the organic electroluminescent display device, in order for the unit light emitter to emit light during the light emission time and express accurate gray scale, the corresponding unit light emitter is rapidly charged with an amount of electric charge corresponding to a potential difference of more than a threshold voltage. It should be allowed to emit light in a steady state.

However, the conventional organic electroluminescent display device as described above has a steady state at the ground level by using a power supply potential level and a ground potential level having a relatively high potential difference as a reference reset potential level for forming a potential difference above a threshold voltage. There has been a problem in that the charging time for reaching the power supply potential level of () is lengthened and the light emitting operation speed of the corresponding unit light emitting body is lowered.

Accordingly, the present invention is to solve the conventional problems as described above, and the object of the present invention is to increase the charge charging speed of the corresponding unit light emitter to improve the light emission operation speed of the corresponding unit light emitter.

In order to achieve the above object, a driving circuit of an organic electroluminescent display device according to the present invention includes a display panel in which a plurality of unit light emitters are arranged in a matrix structure between a plurality of data lines and a plurality of scan lines to display an image; A scan driver and a data driver are applied to the scan line and the data line of the unit light emitter for displaying an image on the panel to reduce the charge charging time of the unit light emitter by applying an operating standby potential which is a potential between the zero level and the power supply level.

The scan driver may include a scan potential unit sequentially applying a zero potential to a scan line in which an image is displayed among the plurality of scan lines, and a power potential to the remaining scan lines in which the image is not displayed, an end point to which the zero potential is applied; Select one of the standby scan potential portion for applying the operation standby potential, the potential applied from the scan potential portion, and the operation standby potential applied from the standby scan potential during the blanking period between the time points at which the zero potential is applied. And a scan potential controller for controlling the potential selection operation of the multiplexer.

The data driver may include a data potential unit for simultaneously applying a power potential to a data line displaying an image on a corresponding unit light emitter among a plurality of data lines, and applying a zero potential to a data line not displaying an image, and during the blanking period. A multi-output selects one of a standby data potential unit for simultaneously applying operating standby potentials to a plurality of data lines, a potential applied from the data potential unit, and a potential applied from the standby data potential unit, and outputs to the corresponding data line. And a data potential controller for controlling the potential selection operation of the multiplexer.

1 is a driving circuit diagram of a conventional organic electroluminescent display device,

2 is a driving circuit diagram of a scan driver applied to the present invention,

3 is a driving circuit diagram of a data driver according to the present invention;

4 is a waveform diagram illustrating an example of a driving signal output from a scan driver and a data driver according to the present invention.

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

21: scan potential 22: power potential

23: zero potential 24: atmospheric scan potential

25, 34: multiplexer 26: scan potential control unit

31: data alignment unit 32: data potential unit

33: standby data potential unit 35: data potential control unit

Hereinafter, the present invention will be described with reference to the accompanying drawings.

2 is a circuit configuration diagram of a scan driver to which the present invention is applied, FIG. 3 is a circuit configuration diagram of a data driver to which the present invention is applied, and FIG. 4 is a driving signal output from the data driver and the scan driver according to the present invention. An example waveform diagram is shown.

First, as shown in FIG. 2, the scan driver applies a zero potential to a scan line on which an image is displayed, and applies a power potential to the remaining scan lines that do not apply the zero potential, thereby providing a unit light emitting unit of the scan line to which the zero potential is applied. A scan potential portion 21 for displaying only an image, a standby scan potential portion 24 for applying an operation standby potential during a blanking period between a scan line to which zero potential is applied and a scan line to which zero potential is applied; A multiplexer 25 for selecting any one of a power potential and a zero potential applied from the scan potential unit 21 and an operation standby potential applied from the standby scan potential unit 24, and outputting the selected potential to the corresponding scan line; And a scan potential controller 26 for controlling the potential selection operation of the flexure 25.

The data driver shown in FIG. 3 includes a data potential section 32 for applying a power potential to a data line where an image is displayed on the unit light emitter among a plurality of data lines, and a zero potential to a data line where the image is not displayed. And a standby data potential unit 33 for simultaneously applying operating standby potentials to a plurality of data lines during the blanking period, and a power potential and zero potential applied from the data potential unit 32 and the standby data potential unit 33. The multiplexer 34 selects one of the operating standby potentials applied to the output line to the corresponding data line, and the data potential controller 35 controls the potential selection operation of the multiplexer 34.

The driving circuit of the present invention configured as described above has a multiplexer 25 under the control of the scan potential control unit 26 during the blanking period between the scan line on which the image is displayed on the unit illuminant and the scan line on which the image is to be displayed on the unit illuminant. ) Connects the standby scan potential unit 24 to the scan line for displaying the image, and the power source potential 22 is connected to the remaining scan lines except for the scan line for displaying the image.

Then, a stand-by voltage is applied to the scan line S1 connected to the standby scan potential 23, and a power potential is applied to the remaining scan lines connected to the power potential 22.

The stand-by voltage is a potential at a level that is between a potential of a power supply level and a potential of zero level, during a blanking period between a scan line in which an image is displayed and a scan line in which an image is to be displayed immediately after, It is a potential applied to a corresponding scan line to display the image.

While this stand-by voltage is applied to the corresponding scan line S1, a stand-by voltage equal to the stand-by voltage is connected to the corresponding scan line. It is applied to each data line D1 of the unit light emitters simultaneously.

After the operation standby charge is applied to the data line D1 and the scan line S1 of the unit light emitting unit during the blanking period, the multiplexer 25 of the scan driver is controlled according to the control of the scan potential controller 26. To the potential potential 23.

Then, the zero potential is applied to the corresponding scan line S1 through the zero potential unit 23 connected to the multiplexer 25 of the scan driver.

Then, while the zero potential is applied to the corresponding scan line S1, the multiplexer 34 of the data driver selects the potential applied from the data potential unit 32 under the control of the data potential controller 35. This potential is applied to the data line.

Therefore, when the difference between the zero potential applied to the scan line S1 of the unit light emitter and the potential applied to the data line exceeds the threshold voltage, the corresponding unit light emitter emits light.

After the image is displayed on the corresponding unit illuminant connected to the scan line S1, the same method as described above is repeatedly performed on the next scan line S2 .... SN, whereby an image of one frame is displayed on the display panel. To be displayed as a whole.

As described above, the operating standby potential is applied to the scan line S1 and the data line D1 of the unit illuminant before the unit illuminant emits light, and then the zero potential and the power are respectively applied to the scan line and the data line of the unit illuminant. The potential is applied to reduce the initial charging time of the unit emitter.

As described in detail above, the driving circuit of the organic electroluminescent display device according to the present invention includes a data line and a scan line of a corresponding unit emitter during a blanking period between a scan line on which an image is displayed and a scan line immediately after the image is displayed. By applying the operating standby potential to the respective unit emitters to reduce the initial charging time (rising time) for the unit emitter to emit light in a steady state and at the same time to erase the remaining charge remaining in the unit emitter, The operating speed of the unit light emitter is improved.

Although the invention has been described in detail only with respect to the specific examples described, it will be apparent to those skilled in the art that various modifications and variations are possible within the spirit of the invention, and such modifications and variations belong to the appended claims.

Claims (3)

A display panel in which a plurality of unit light emitters are arranged in a matrix structure between the plurality of scan lines and the plurality of data lines; A scan driver for sequentially applying zero potential to the plurality of scan lines and applying an operation standby potential to the corresponding scan line during a blanking period between an end point to which zero potential is applied and a time point at which the zero potential is applied; And a data driver for applying an operation standby potential to each data line connected to the unit light emitting unit during the blanking period. The method of claim 1, wherein the scan driver; A scan potential unit for sequentially applying zero potential to scan lines in which images are displayed among the plurality of scan lines, and power potential to remaining scan lines in which images are not displayed; A standby scan potential portion for applying an operation standby potential during the blanking period between the end point to which the zero potential is applied and the time point at which the zero potential is applied; A multiplexer for selecting one of a potential applied from the scan potential portion and an operation standby potential applied from the standby scan potential portion and outputting the selected multiplexer to a corresponding scan line; And a scan potential controller for controlling the potential selection operation of the multiplexer. 2. The system of claim 1, wherein the data driver comprises: A data potential section for applying a power potential to a data line in which an image is displayed on the unit light emitting unit among the plurality of data lines, and a zero potential to a data line in which the image is not displayed; A standby data potential unit for simultaneously applying an operation standby potential to each of the plurality of data lines during the blanking period; A multiplexer which selects one of a potential applied from the data potential section and a potential applied from the standby data potential section and outputs the selected data line to a corresponding data line; And a data potential controller for controlling the potential selection operation of the multiplexer.