KR100845185B1 - Drive Method for Extending Life of a Passive Matrix Organic Electro Luminescence Display - Google Patents

Abstract

The present invention relates to a long life driving method of a passive organic EL display that can extend the service life of the display by adjusting the shape of the voltage waveform supplied to the organic EL display sheet composed of a large number of organic EL pixels. By installing a relaxation capacitor in parallel with the organic EL element at the output of the driving IC of the organic EL display, the instantaneous sudden change when switching from quenching to luminescence or luminescence to quenching during the driving process of the passive organic EL display By buffering the driving voltage, it is characterized in that the voltage gradient in the section in which the driving voltage rises and the section in which the driving voltage falls is gently adjusted in the form of a logarithmic curve.

OLED, display, lifespan, driving, pixel

Description

Long life driving method of passive organic EL display

1 is a circuit diagram showing the structure of a typical organic EL display.

2 is a timing diagram showing a conventional voltage waveform applied to an organic EL display.

3 is a graph showing a change in luminance of the organic EL pixel according to the magnitude of the voltage waveform shown in FIG.

4 is a timing diagram showing a driving waveform by the driving method according to the present invention;

Figure 5 is a Thevenin equivalent circuit diagram showing an embodiment for generating a drive waveform by the driving method according to the present invention.

The present invention relates to a long life driving method of a passive organic EL display, and more particularly, it is possible to extend the service life of the display by adjusting the shape of the voltage waveform supplied to the organic EL display sheet composed of a myriad of organic EL pixels. It relates to a long life driving method of a passive organic EL display.

In general, the display device is provided with lighting means for generating light.

The lighting means is turned on by receiving a separate power, and the light generated from the lighting means is irradiated to the front from the rear of the display means (LED panel, etc.) installed on the front.

As such, a separate lighting means must be installed on the display means which does not generate light.

On the other hand, recently, an organic EL display capable of emitting light has been developed and used so that it can be used without using a separate lighting means.

The organic EL display is composed of numerous organic EL pixels, each of which is connected to a horizontal scan electrode and a vertical data electrode.

The emission or quenching of the organic EL pixel is determined according to the scan voltage applied to the scan electrode and the data voltage applied to the data electrode.

That is, the operation is as follows.

When the frame is started according to the vertical synchronization signal, as shown in FIG. 1, the first scan electrode is selected and is instantaneously changed from the unselected scan voltage V _sH (10V) to the selected scan voltage V _sL (0 V). Large current flows and then stabilizes with small current.

In the meantime, the data electrodes also instantaneously supply the emission voltage V _dH (10 V) or the extinction voltage V _dL (0 V) according to the emission or quenching data, so a very large current flows and the organic EL element accumulates fatigue. .

When 10 V is applied to the data electrode while the scan electrode is maintained at 0 V, 10 V is supplied to the organic EL pixel and light is generated. When 0 V is applied to the data electrode, 0 V is supplied to the organic EL pixel to quench the light.

Since the unselected scan electrode pixels maintain the unselected scan voltage of 10 V and supply 10 V or 0 V to the data electrodes, the two electrode voltages of the organic EL pixel become 0 V or −10 V to always maintain the quenching state.

At the end of the selection period of the first scan electrode, the scan voltage is instantaneously increased from 0V back to the first 10V, a very large current flows, and the organic EL element accumulates fatigue.

The driving voltage applied to the pixel is determined by the voltages applied to the scan electrode and the data electrode, and when the sum of the selection period and the non-selection period is expressed on the time axis, a square wave shape similar in magnitude to the positive voltage and the negative voltage as shown in FIG. Becomes the voltage of.

When the second scan electrode is selected, the second scan electrode is also instantaneously reduced from 10V to 0V so that a very large current flows and stabilizes with a small current. The pixels emit or quench according to a voltage of 10V or 0V applied to the data electrode.

In this way, when the scan is completed to the last scan electrode, one frame is completed, and the scan is returned to the first scan electrode again.

During the repetition of the frame, the scan electrode repeats the instantaneous change from the unselected voltage to the select voltage and the select voltage to the unselected voltage, and the data electrode repeats the instantaneous change from the extinction voltage to the emission voltage or from the emission voltage to the extinction voltage. Therefore, the organic EL element plays a role of shortening display life time due to very large current flow and fatigue accumulation.

10V described above is a representative voltage because the scan voltage V _sH and the light emission voltage V _dH applied to the scan electrode and the data electrode are about 10 V and have similar values.

The brightness of the passive organic EL display is adjusted by adjusting the pulse width modulation (PWM) of the driving pulse or the amplitude of the driving pulse (PAM) within the selection time.

On the other hand, the organic EL pixel has both a capacitor and a resistor at the same time. In addition, the driving voltage is a square wave voltage similar in magnitude to the positive and negative voltage as shown in FIG. Therefore, in the related art, when the driving voltage changes instantaneously, a very large current flows due to an internal capacitor of the organic EL element and fatigue accumulates, thereby shortening the life time of the organic EL element.

The present invention has been invented to solve the above problems, the object of which is to gradually change the driving voltage to reduce the current flowing, to reduce the fatigue can absorb the instantaneous voltage change to improve the life of the organic EL display By using a capacitor, a relaxation capacitor is connected in parallel with an organic EL element to an output portion of a data driving integrated circuit (IC) or a scan driving IC to absorb a sudden change in supply voltage, thereby reducing the voltage gradient. It is to provide a long life driving method of the adjustable passive organic EL display.

Referring to the characteristic configuration of the present invention for achieving the above object is as follows.

In the long life driving method of the passive organic EL display of the present invention, a relaxation capacitor is installed in parallel with the organic EL element at the output of the driving IC of the passive organic EL display, so that By buffering the suddenly changing driving voltage when switching from luminescence to luminescence to quenching, it is possible to smoothly adjust the voltage gradient in the form of a logarithmic curve in the period in which the driving voltage rises and the section in which the driving voltage falls. It features.
Meanwhile, the relaxation capacitor installed in the driving IC output portion of the passive organic EL display may be replaced by a digital to analog converter. That is, the D / A converter is installed inside the driving IC to convert the digital voltage signal into an analog voltage so that the voltage change when the passive organic EL display is switched from extinction to emission or from emission to extinction is smoothly performed. Convert to a signal. The use of such a D / A converter is a simple substitute for using a relaxation capacitor as described above, and will be said to fall within an equal range.

Referring to the present invention having such characteristics in detail as follows.

4 is a timing diagram showing a driving waveform by the driving method according to the present invention, Figure 5 is a Thevenin equivalent circuit diagram showing an embodiment of generating a driving waveform by the driving method according to the present invention.

As referred to herein, since the organic EL element has a capacitor and a resistor therein, a current proportional to the voltage gradient flows when the driving voltage changes. In addition, the current flowing through the capacitor is represented by Equation (1).

[Equation 1]

Equation 1 indicates that a very large current flows when the driving voltage is momentarily changed, and the organic EL element may generate fatigue and shorten its life time. The solution is to use a capacitor that can absorb instantaneous voltage changes.

When a relaxation capacitor (C _R ) is connected in parallel with the organic EL element to the output of the data driver IC or the scan driver IC, it is possible to gradually change the supply voltage that is changed momentarily.

You can also adjust the voltage slope by adjusting the relaxation capacitor (C _R ) capacitance.

With the relaxation capacitor connected, the OLED display works as follows.

When a frame is to start scanning the first scan electrode driving IC of the internal is selected is instantaneously changed to the selection scan voltage V _sL (0V) in the non-scanning selection voltage V _sH (10V) in accordance with the vertical synchronizing signal.

However, the relaxation capacitor gradually decreases the driving voltage because it changes the supply voltage momentarily with discharge. In the meantime, the current gradually decreases, reducing the fatigue of the organic EL element. In addition, the data electrodes supply the light emission voltage V _dH or the extinction voltage V _dL according to the light emission or extinction data.

If the scan electrode maintains 0V and the light emitting voltage is supplied to the data electrode momentarily, the relaxation capacitor connected to the data electrode increases while charging the voltage, so that the driving voltage gradually increases and the current flow decreases to reduce the fatigue of the organic EL element. give. When the extinction voltage V _dL is applied to the data electrode, 0 V is maintained as it is, so that the organic EL pixel is extinguished without current.

Since the unselected scan electrode pixels maintain a positive scan voltage V _sH (10V) and supply a light emission voltage (V _dH ) or an extinction voltage (V _dL ) to the data electrode, the two electrode voltages of the organic EL pixel are V _dH −. It _becomes V _sH (0V) or V _dL -V _sH (-10V) and always keeps extinction.

At this time, however, 0V or -10V may be instantaneously applied, but a relaxation capacitor connected to the data electrode absorbs the supply voltage, gradually reducing the driving voltage and the current flowing and reducing fatigue.

The first end of the selection period of the second scan electrodes is increased to a selected scanning voltage (V _sL) (0V) the first non-selected scanning voltage (V _sH) (10V) in the back.

However, at this time too much current does not flow because the relaxation capacitor increases while charging the supply voltage. As shown in FIG. 4, when the selection period and the non-selection period are combined, the long-life driving voltage waveform is shown. As shown in FIG. 4, the voltage slope in the section in which the driving voltage rises and the section in which the driving voltage falls is smooth in the form of a logarithmic curve. Adjusted.

In this way, when the scan is completed to the last scan electrode, one frame is completed, and the scan returns to the first scan electrode and repeats the scan.

As such, the present invention adjusts the rise time and the fall time of the driving waveform supplied to the organic EL pixel so that the electric current flows less and the fatigue of the organic EL element is reduced, thereby extending the service life.

Claims (9)

A relaxation capacitor is installed at the output of the driving IC of the passive organic EL display in parallel with the organic EL element so that it suddenly changes suddenly from extinction to emission or from emission to extinction during the driving process of the passive OLED display. A method of driving a long lifespan of a passive organic EL display, characterized in that the slope of the driving voltage is increased and the voltage gradient in the section in which the driving voltage falls is adjusted slowly in the form of a logarithmic curve. delete delete delete delete delete delete delete delete

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