KR100386745B1 - Driving circuit of organic electro luminescence display element - Google Patents

Abstract

Power is supplied at a level corresponding to the number of unit emitters that are turned on among the plurality of unit emitters provided in the display panel so that the plurality of unit emitters output light with the same luminance.

The current according to the number of unit light emitters is detected and the power supply unit is controlled according to the detected current to supply operating power to the scan driver and the data driver so that the plurality of unit light emitters of the display panel all operate under the same luminance. The image data processing control unit processes predetermined image data and controls the processed image to be displayed on the display panel, and under the control of the image data processing control unit, the scan driver and the data driver control the scan lines and data of the display panel. Each scan drive signal and data drive signal are output to a line to display a predetermined image. When the scan driver outputs a scan drive signal, the current detection unit detects a current flowing through the line, and the image is detected according to the detection signal of the current detection unit. Data processing control unit output power of the power supply unit It controls the bell.

Description

Driving circuit of organic electroluminescent display element

The present invention relates to a driving circuit of an organic electroluminescent display element (hereinafter, abbreviated as 'organic EL display element') that displays predetermined letters, numbers, symbols, images, videos, etc. using electroluminescence. It's about the furnace.

In general, a flat panel display (FPD) device is classified into a device using an inorganic material and a device using an organic material based on the material used. Examples of devices using inorganic materials include plasma display panels (PDP) using PL (Photo Luminescence) from phosphors, and field emission display (FED) devices using CE (Cathode Luminescence). Examples of the device using the above include liquid crystal display (LCD) and organic EL display devices which are widely used in various fields.

The organic EL display device has a response speed of about 30,000 times faster than LCD which is currently widely used, and thus, it is possible to implement a video, and also has an advantage of wider viewing angle and high luminance by emitting light by itself. The display device of the spotlight.

Such organic EL display devices are classified according to the type of organic material to be used, and there are a low molecular organic EL display device using a functional monomolecular organic material having a small molecular weight and a high molecular organic EL display device using a high molecular weight organic polymer.

The organic EL display device typically forms a transparent indium tin oxide (ITO) layer as a cathode on a transparent glass substrate, and sequentially forms an organic layer as a light emitting layer and a cathode as a cathode.

In such an organic EL display device, a unit light emitting body is formed of an anode electrode, a light emitting layer, and a cathode electrode.

As shown in FIG. 1, a plurality of unit light emitters 14 are arranged in a matrix structure between a plurality of data lines 10 and a plurality of scan lines 12 to form a unit light emitter ( The anode electrodes of the fourteen elements are connected to the data line 10, and the cathode electrode of the unit light emitter 14 is connected to the scan line 12 to form one display panel 16.

2 is a conventional driving circuit diagram. Here, reference numeral 20 denotes an image data processing control unit for controlling display of an image on the display panel 16 by processing predetermined image data, and reference numeral 22 denotes the display panel under control of the image data processing control unit 20. A scan driver for outputting a scan drive signal to the scan line 12 of (16), the code 24 is a data drive to the data line 10 of the display panel 16 under the control of the image data processing control unit 20 Data driver that outputs signals.

The conventional drive circuit configured as described above processes the predetermined image data to be displayed by the image data processing control unit 20, controls the scan driver 22 to output a scan drive signal, and according to the processed image data. The data driver 24 is controlled so that the data driver 24 outputs a predetermined data drive signal in accordance with the image data.

As such, the scan driving signal output from the scan driver 22 is applied to the cathode electrode of the unit light emitter 14 through the scan line 12 of the display panel 16, and the predetermined data output from the data driver 24 is output. The driving signal is applied to the anode electrode of the unit light emitter 14 through the data line 10 of the display panel 16 so that the unit light emitter 14 selectively emits light and displays a predetermined image.

Here, the unit emitters 14 emit light according to the voltage difference between the driving signals applied to the data line 10 and the scan line 12, and the gray scale is displayed by the time difference between the voltages generated.

That is, when the voltage difference applied to the data line 10 and the scan line 12 exceeds the threshold voltage of the unit light emitter 14, the unit light emitter 14 emits light, and the amount of current flowing at this time. And the gray level is displayed by varying the amount of light output according to the intensity. When the threshold voltage is not exceeded, the unit light emitter 14 does not emit light.

According to the driving method of the current-driven organic EL display element, a power source used as a power source for a data driver and a scan driver that drives the data line and the scan line when the current flow is severely changed as shown in the video display. There is a case where it is not able to actively cope with the load fluctuation of fast output.

For example, as shown in FIG. 3, conventionally, the power source required for the data driver and the scan driver is always configured as a system in which the power of the load is manually operated. At this time, due to the voltage difference due to the passive correspondence of the power applied between the high-load scan line and the low-load scan line 12, the scan line 12 can see a difference in luminance amount. The difference in the quantity of light may be caused by a difference in luminance generated in the screen of the display panel 16 by spots and horizontal lines.

That is, among the plurality of unit light emitters 14 having the cathode electrode connected to the scan line 12, the scan line 12 and the small number of unit light emitters 14 for operating the unit light emitters 14 are operated. When the scan driving signal is output to the scan line 12, the current flowing through the large number of unit light emitters 14 and the small number of unit light emitters 14 is different, so that a luminance difference occurs, and the display panel 16 is generated. ), Smudges or horizontal lines will appear on the screen.

This indicates a decrease in screen uniformity, and the image is actually displayed distorted.

In addition, a problem such as a short may occur in a specific portion of the panel of the organic EL display device, which may cause the destruction of a driver integrated device, etc., which may occur when excessive current flows temporarily. There was a problem such as not being able to operate stably with respect.

Accordingly, an object of the present invention is to supply power to the scan driver and the data driver according to the number of unit light emitters among the plurality of unit light emitters provided in the display panel so that the plurality of unit light emitters output light at the same luminance. The present invention provides a driving circuit for an organic electroluminescent display device.

According to the driving circuit of the organic electroluminescent display device of the present invention for achieving the above object, the current according to the number of unit light-emitting unit is detected, and the power supply unit is controlled according to the detected current to the scan driver and the data driver By supplying the operating power so that the plurality of unit light-emitting bodies of the display panel all operate at the same brightness, the image data processing control unit processes predetermined image data and controls the processed image to be displayed on the display panel, and the image data processing Under the control of the control unit, the scan driver and the data driver respectively output the scan driving signal and the data driving signal to the scan line and the data line of the display panel so that a predetermined image is displayed, and the scan driver outputs the scan driving signal. The current detector detects the current flowing in the According to the detection signal of the detection image data processing control unit controls the output power level of the power supply.

1 is a view illustrating a modeling relationship between a data line and a scan line of a general organic electroluminescent display device.

2 is a conventional driving circuit diagram,

3A and 3B illustrate driving signals applied to a data line and a scan line by a conventional driving circuit as an example.

4 is a block diagram showing a driving circuit of the present invention;

5 is a detailed circuit diagram of the driving circuit of the present invention.

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

40: display panel 41: image data processing control unit

42: scan driver 43: data driver

44: current detector 45: power supply

410: comparison means R1: resistance for current detection

Hereinafter, a driving circuit of the organic electroluminescent display device of the present invention will be described in detail with reference to the accompanying drawings of FIGS. 4 and 5.

4 is a block diagram showing a driving circuit of the present invention, Figure 5 is a detailed circuit diagram.

As shown in the drawing, a plurality of unit light emitters are connected in a matrix, and the display panel 40 displays a predetermined image, and an image which processes and processes the predetermined image data to be displayed on the display panel 40. According to the data processing control unit 41 and the control of the control unit 41, the scan driving signal and the data driving signal are respectively output to the scan line and the data line of the display panel 40, and the predetermined values are output to the display panel 40. A scan driver 42 and a data driver 43 for displaying an image, a current detector 44 for detecting a current flowing when the scan driver 42 outputs a scan drive signal, and the image data processing controller And a power supply 45 for outputting power under the control of 41 to supply the scan driver 42 and the data driver 43 with operating power.

The current detector 44 may include a current detection resistor R1 for converting and detecting the output current of the scan driver 42 into a voltage, a resistor R2 for shaping the voltage across both ends of the current detection resistor R1, and It consists of the waveform shaping part which consists of capacitor | condenser C1.

The image data processing control section 41 compares the output voltage of the waveform shaping section with a preset reference voltage Vref and controls the power supply section 45 according to a comparison result to control output power. ) Is provided.

In the driving circuit of the present invention configured as described above, the image data processing control unit 41 displays the power supply unit 45 outputting a predetermined level of power to supply the operating power to the scan driver 42 and the data driver 43. The predetermined image data to be processed is processed, and when the processing of the image data is completed, the scan driver 42 and the data driver 43 are controlled in accordance with the image data.

Then, the scan driver 42 and the data driver 43 output the scan driving signal and the data driving signal under the control of the image data processing controller 41, and the output scan driving signal and the data driving signal are displayed on the display panel 40. ) Is applied to the anode electrodes of the plurality of unit light emitters through the scan line and the data line to selectively emit light and display a predetermined image.

Here, the scan driver 42 outputs a predetermined scan driving signal to output a predetermined current when operating the corresponding unit light emitter. That is, in the scan driver 42, for example, a MOS (Metal Oxide Semiconductor) transistor is connected in series to a plurality of scan lines provided in the display panel 40, and to control the image data processing control unit 41. Accordingly, the plurality of MOS transistors are selectively operated to allow current to flow through the corresponding scan line, and the corresponding unit emitters emit light in accordance with the data driving signal output from the data driver 43. Therefore, the scan driver 42 outputs a current corresponding to the number of unit emitters in which the data driver 43 emits light according to the data driving signal among the plurality of unit emitters of the corresponding scan line outputting the scan driving signal.

As described above, the predetermined current output from the scan driver 42 flows to the ground through the resistor R1 for the current detector of the detector 44, and both ends of the resistor R1 output the predetermined current output from the scan driver 42. The voltage according to the level is generated, and the voltage across the resistor R1 is smoothed by the capacitor C1 through the resistor R2 and input to the image data processing control section 41.

Then, the comparing means 410 of the image data processing controller 41 compares the detection voltage input from the current detector 44 with the preset reference voltage Vref, and generates a pulse signal having a predetermined width according to the comparison result. The control signal is outputted by the power supply unit 45.

The power supply unit 45 is, for example, a switching mode power supply (SMPS), and the switching operation is controlled according to a control signal having a predetermined width output from the image data processing control unit 41 so that the scan driver 42 and The data driver 43 is supplied with an appropriate level of power in accordance with the number of unit light emitters currently being emitted.

As described in detail above, the present invention provides a plurality of units of a display panel by detecting a current according to the number of unit emitters that emit light, and supplying operating power to a scan driver and a data driver by controlling a power supply unit according to the detected current. The light emitters all operate at the same luminance, and thus a predetermined image can be displayed clearly without spots or horizontal lines on the screen of the display panel.

Claims (3)

A display panel in which a plurality of unit light emitters are connected in a matrix and display a predetermined image; An image data processing control unit which controls an image which has processed and processed predetermined image data to be displayed on the display panel; A scan driver and a data driver for respectively outputting scan driving signals and data driving signals to scan lines and data lines of the display panel under the control of the image data processing controller to display a predetermined image; A current detector for detecting a current flowing when the scan driver outputs a scan driving signal; And A power supply unit for outputting power under the control of the image data processing control unit and supplying power to the scan driver and the data driver as operating power; And the image data processing control unit is configured to control the output power level of the power supply unit according to the detection signal of the current detection unit. According to claim 1, wherein the current detector; A current detection resistor for detecting an output current of the scan driver; And And a waveform shaping unit for waveform shaping the voltage across the current detecting resistor and inputting the waveform to the image data processing control unit. The image processing apparatus according to claim 1, wherein the image data processing control unit; And a comparison means for comparing the output signal of the current detector with a preset reference voltage and controlling the output power level of the power supply according to the comparison result.