KR100571002B1 - Organic EL driving circuit - Google Patents

Abstract

       The present invention relates to an organic EL driving circuit which compensates for the voltage drop of the scan line due to the transparent electrode resistance of the data electrode when the organic EL panel is driven to prevent uneven luminance between scan lines.

       A switching circuit for applying a switching signal to a scan line and a data line of an organic EL panel; A control circuit for applying a control signal to the switching circuit; And a voltage compensation circuit configured to receive a control signal of the control circuit and to control a predetermined driving voltage variable width and supply a variable driving voltage to the switching circuit.

Organic EL, EL Drive, Scan Line

Description

       Organic EL driver circuit

       1 is a conventional organic EL driving circuit diagram

       2 is an organic EL driving circuit diagram of the present invention;

       3 is a constant voltage driving circuit diagram of the present invention.

 * Explanation of symbols for the main parts of the drawings *

   10; Panel 11; Switching circuit

   12; Control circuit 13; Constant current circuit

   20; Voltage compensation circuit 21; Voltage Variation Control Unit

   22; Voltage variable part

       The present invention relates to an organic EL driving circuit, and more particularly, to an organic EL driving circuit which compensates a voltage drop of a scan line due to a transparent electrode resistance of a data electrode when driving an organic EL panel to prevent unevenness of luminance between scan lines. It is about.

      In general, in the case of the organic EL panel, the light emission luminance is changed in proportion to the amount of current flowing through each cell.

However, in the organic EL panel, a voltage drop occurs due to the transparent electrode (ITO) resistance of the data electrode, and the voltage drop increases gradually toward the lower scan line.

In other words, assuming that the pixel size is 300 μm × 300 μm, a 5 ”panel, and the transparent electrode (ITO) resistance is 10 Ω / □, the difference in the transparent electrode (ITO) resistance between the first scan line and the last scan line is 10 Ω / □? It becomes about * 4 "/ 300 micrometers = 3.387 kPa.

       Therefore, in the case of the panel, as the scan line moves toward the lower scan line, the amount of current decreases due to the voltage drop caused by the transparent electrode resistance, thereby lowering the brightness of the panel.

In order to prevent such deterioration of the luminance of the panel and to maintain the emission luminance of the organic EL panel uniformly, a constant current is supplied and driven.

That is, in the case of the panel, as shown in FIG. 1, the scan line and the data line are used to prevent the luminance decrease caused by the lowering of the current as the lower scan line is caused by the transparent electrode resistance. A configured panel 10; A switching circuit (11) for supplying a switching drive signal to each line of the panel (10); A control circuit 12 for applying a control signal to the switching circuit 11; A constant current circuit 13 is formed in each of the data lines DATA line of the panel 10, and when the panel 10 is driven, a constant current is supplied to each data line through the constant current circuit 13 to supply the respective scan lines. By maintaining a constant current, luminance unevenness has been eliminated in each scan line.

However, in the case of the organic EL driving circuit, since a constant current circuit must be configured for each data line of each panel, not only the configuration of the entire driving circuit according to each configuration of the constant current circuit is significantly complicated, but also the size when manufacturing the driving circuit. Due to the increase of the price can not be simplified, and the price is also raised.

       Therefore, an object of the present invention is to compensate for the voltage drop of the scan line according to the transparent electrode resistance of the data electrode when driving the organic EL panel, thereby eliminating luminance unevenness and degradation between the scan lines of the panel.

       The present invention provides a switching circuit for applying a switching signal to scan lines and data lines of an organic EL panel; A control circuit for applying a control signal to the switching circuit; And a voltage compensation circuit configured to receive a control signal of the control circuit and control a predetermined driving voltage variable width and supply a variable driving voltage to the data line.

       Therefore, according to the present invention, by supplying a variable controlled voltage to each data line when driving an organic EL panel, the voltage drop between each scan line according to the transparent electrode resistance of the data electrode is eliminated, so that a uniform driving voltage is applied to each scan line. Since it is possible to maintain the luminance unevenness of the panel can be eliminated.

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

       Fig. 2 is an organic EL driving circuit diagram of the present invention, and Fig. 3 is a constant voltage driving circuit diagram of the present invention, comprising: a panel 10 composed of a scan line and a data line; A switching circuit (11) for supplying a switching drive signal to each line of the panel (10); A control circuit 12 for applying a control signal to the switching circuit 11; The voltage compensation circuit 20 receives a control signal from the control circuit 12 and supplies a predetermined driving voltage variable width control and a variable voltage to the data line of the panel 10 through the switching circuit 11. It is made up.

       The voltage compensating circuit 20 includes: a voltage variable width control unit 21 for controlling a voltage width by a voltage dropped arbitrarily set according to the resistance of the transparent electrode of the panel 10; The voltage variable width controller 21 is configured as a voltage variable part 22 for supplying a voltage having a variable voltage width.

       According to the present invention configured as described above, the control signals from the control circuit 12 to the switching circuit 11 connected to the scan line and the data line of the organic EL panel 10 in a line-sequential manner. Will be authorized.

       Accordingly, in the switching circuit 11, the switching drive is sequentially performed along the lower scan line and the data line from the upper scan line and the data line of the panel 10 while the switching drive is sequentially performed by the line sequential method of the control circuit 12. In addition, the control circuit 12 applies a control signal to the voltage variable part 22 of the voltage compensating circuit 20 to cause the voltage variable part 22 to apply a variable voltage to the upper portion of the panel 10. Supply from the scan line and data line to the lower scan line and data line.

       In this case, the variable voltage supplied from the voltage variable part 22 corresponds to a voltage width corresponding to a voltage drop generated by the voltage variable width controller 21 according to the transparent electrode ITO resistance of the data electrode of the panel 10. Supply a preset controlled voltage.

       Therefore, the scan line and the data line of the panel 10 are supplied from the top to the bottom while supplying a variable voltage in which the voltage width is increased by the voltage drop caused by the resistance of the transparent electrode ITO of the panel 10. In the scan line and the data line, the uniform driving voltage is maintained as a whole, so that the light emission luminance of the panel 10 can be maintained evenly.

As described above, according to the present invention, the voltage drop of each scan line caused by the resistance of the transparent electrode of the organic EL panel is controlled by a predetermined driving voltage variable width and is a voltage compensation circuit for supplying a variable driving voltage. Since the voltage is increased and supplied, each scan line of the panel is supplied with a compensated voltage to maintain a uniform voltage at each scan line, thereby eliminating unevenness in luminance due to maintaining a uniform voltage throughout the panel. Will provide an effect.

Claims (2)

       A switching circuit for applying a switching signal to the scan line and the data line of the organic EL panel; An organic EL driving circuit comprising a control circuit for applying a control signal to the switching circuit, wherein the predetermined predetermined control voltage variable width control and a predetermined driving voltage are supplied to the switching circuit in response to a control signal of the control circuit. An organic EL driving circuit comprising a voltage compensating circuit.        The voltage compensating circuit of claim 1, further comprising: a voltage variable width controller configured to control a width of the voltage by a voltage that is arbitrarily set according to the resistance of the transparent electrode of the panel; And a voltage variable part for supplying a voltage having a variable voltage width in the voltage variable width control part.

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