KR20020094601A - Image processing system of organic electro luminescence display with brightness control circuit - Google Patents

Abstract

PURPOSE: An image processor of an organic electroluminescent display device comprising a luminance control circuit is provided which can control a luminance of a picture data according to the selection of a user. CONSTITUTION: A pulse width modulation part(13) performs a pulse width modulation of picture data according to each gray level and then outputs it. An output circuit part outputs a data driving signal to a corresponding data line according to the picture data being output by being modulated in the pulse width modulation part. And a luminance control part and a gray level control part control the data driving signal being output to the corresponding data line according to a luminance level and a gray level selected by a user.

Description

Image processing system of organic electroluminescence display with brightness control circuit

The present invention relates to an image processing apparatus of an organic electroluminescent display element (hereinafter referred to as an 'organic EL display element') having a luminance control circuit.

In general, in the organic EL display device, a plurality of unit emitters each including a transparent ITO layer, an organic layer, and a cathode are formed in a matrix structure, and a data driving signal and a scan driving signal are respectively applied to data lines and scan lines of each of the plurality of unit emitters. When the potential difference between the data drive signal and the scan drive signal exceeds the threshold voltage of the corresponding unit light emitter, the corresponding unit light emitter emits light to display an image.

In the organic EL display device having such light emission characteristics, the gray level of the image data has been expressed by controlling the application time of the current flowing through the data line of the corresponding unit light emitter, and FIG. 1 is a diagram for explaining this.

As shown in Fig. 1, a conventional image processing apparatus of an organic EL display device includes a driving transistor having a constant current characteristic in a corresponding data line D1, for example, a metal oxide semiconductor (MOS) field effect transistor (TR1). By connecting it to the pulse width modulator 13 and turning on and off the driving MOS field effect transistor TR1 in accordance with the pulse width modulated and output pulse signal to control the current flowing to the corresponding data line D1. Various gradations of image data have been expressed.

The pulse width modulator 13 compares a counter 14 that cyclically outputs a count value counting a clock signal, and a count bit value by comparing the count bit value output by the counter 14 with the bit value of the image data. Comprising a comparator 15 for outputting a pulse signal having a width until the same as the bit value of the image data to the output circuit unit 16, the width of the pulse signal output from the output circuit unit 16 is an image It depends on the gray level of the data. Fig. 2 is a diagram showing the actual circuit configuration of the organic electroluminescent display element image processing apparatus having such an operation configuration.

In addition, as shown in FIG. 1, the conventional image processing apparatus of the organic EL display device has the same dynamic resistance characteristics as the gray scale control transistor 12, for example, a MOS (Metal Oxide Semiconductor) field effect transistor (TR2). In accordance with the gray level signal selected by the user through the gray level selection unit 11, the gray scale controller 12 adjusts the voltage between the drain sources V _ds of the MOS field effect transistor TR2 for gray scale control. By controlling the drain current I _d proportional to the predetermined value between the drain and source voltages V _ds , the gradation of the image data could be arbitrarily adjusted according to the user's selection.

According to the image processing apparatus of such an organic EL display element, a means for adjusting the brightness of the image data is not provided separately in the driving circuit of the general organic EL display element, and is processed dependently according to the amount of current to be adjusted during gradation adjustment. Has been.

That is, the brightness of the image is not controlled through a separate brightness control means, but when the user selects a predetermined gray level to adjust the gray level of the image, the corresponding data line in the driving MOS field effect transistor according to the gray level. In proportion to the amount of the drain current flowing to the.

Therefore, not only the luminance of the image data can not be arbitrarily adjusted according to the user's selection, but also the luminance representation that is dependent on the gradation representation due to the limitation of the number of wirings or the counter frequency also has a practical limitation. There was a problem that good display quality in the film was not obtained properly.

Accordingly, an object of the present invention is to solve the conventional problems as described above, and to provide an image processing apparatus of an organic EL display device capable of adjusting the brightness of image data according to a user's selection.

In order to achieve the above object, an image processing apparatus of an organic light emitting display device having a luminance adjusting circuit according to the present invention adds image data and luminance data corresponding to a luminance level selected by a user, and adds the result corresponding to the addition. A luminance controller 52 for outputting data, a pulse width modulator 13 for pulse width modulating and outputting the added data output from the luminance controller 52, and a pulse in the pulse width modulator 13; An output circuit unit 55 for outputting a data driving signal to a corresponding data line according to the width-modulated addition data and a gray level for adjusting a data driving signal applied to the corresponding data line from the output circuit unit 55 according to a gray level signal selected by a user. It is characterized by consisting of the adjusting unit (10).

1 is a block diagram showing an image processing apparatus of a general organic electroluminescent display device;

2 is a circuit diagram showing an actual circuit of a conventional image processing apparatus.

3 is a block diagram showing an embodiment of the present invention,

4 is a circuit diagram showing an actual circuit of an output circuit part to which the present invention is applied.

Fig. 5 is a block diagram showing another embodiment of the present invention.

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

10: gradation adjustment unit 11: gradation selection unit

12: gradation controller 13: pulse width modulator

14: counter 30, 50: luminance control unit

31, 51: luminance selector 32, 52: luminance control unit

33, 40, 55: output circuit 53: memory

54: adder

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

First, an image processing apparatus of an organic electroluminescent display device as a first embodiment of the present invention will be described with reference to FIGS.

The image processing apparatus shown in FIG. 3 includes a pulse width modulator 10 for outputting pulse width modulated image data according to each gray level, and image data output by pulse width modulated by the pulse width modulator 10. An output circuit unit 33 for outputting the data driving signal to the corresponding data line, and a brightness adjusting unit 30 for respectively adjusting the data driving signal outputting to the corresponding data line according to the luminance level and the gradation level selected by the user; It consists of a gray scale control unit (10).

In addition, the brightness adjusting unit 30 and the gray scale adjusting unit 10 are provided to the brightness selecting unit 31 and the gray selecting unit 11 and the brightness level signal and the gray level signal selected by the user. Accordingly, each of the luminance controller 32 and the gray scale controller 12 that controls the data driving signal applied to the corresponding data line is configured.

In the image processing apparatus of the present invention configured as described above, when a user selects a desired luminance level through the luminance selector 31, the luminance control unit 32 senses a signal corresponding to the luminance level, and the luminance level signal. The amount of current applied to the corresponding data line from the output circuit 33 is controlled accordingly.

As shown in FIG. 4, the output circuit unit 33 includes a device having a dynamic resistance characteristic such as a luminance control transistor, for example, a metal oxide semiconductor (MOS) field effect transistor (TR3), and the luminance control unit ( 32, the MOS field effect transistor TR3 having the dynamic resistance characteristic adjusts the amount of current flowing to the corresponding data line according to the control signal output from the luminance controller 32.

That is, the MOS field effect transistor TR3 adjusts the voltage V _ds between the drain electrode and the source electrode which varies in proportion to the magnitude of the luminance control signal applied to the gate electrode, and between the drain electrode and the source electrode. The amount of current flowing from the MOS field effect transistor TR3 to the corresponding data line D1 is adjusted by adjusting the width of the depletion layer whose size varies in inverse proportion to a predetermined value according to the voltage V _ds .

For example, when a user raises a predetermined brightness level through the brightness selector 31, the brightness controller 32 senses the raised brightness level, and transmits a control signal corresponding to the brightness level to the MOS field effect transistor ( To the gate electrode of TR3). Then, according to the control signal applied to the gate electrode, the voltage (V _ds ) magnitude between the gate electrode and the source electrode is increased, and the width of the depletion layer decreases in inverse proportion to the increased voltage, so that the amount of current flowing to the corresponding data line is reduced. It increases as the width of the depletion layer decreases.

Thus, the brightness of the image displayed on the display panel is increased by the amount of the increased current. On the contrary, when the user lowers the predetermined brightness level through the brightness selector 31, the brightness controller 32 lowers the lowered brightness level. The control signal corresponding to the luminance level is applied to the gate electrode of the MOS field effect transistor TR3.

Then, according to the control signal applied to the gate electrode, the voltage magnitude between the gate electrode and the source electrode is reduced, and the width of the depletion layer increases in inverse proportion to the reduced voltage magnitude, and the amount of current flowing to the corresponding data line is increased. As the width increases, the luminance of the image displayed on the display panel decreases.

Next, a second embodiment of the present invention will be described with reference to FIG.

The image processing apparatus shown in FIG. 5 includes a luminance adjusting unit 50 for adding image data and luminance data corresponding to a luminance level selected by a user, and outputting addition data corresponding to the addition result, and the luminance adjusting unit. The pulse width modulator 13 outputs the pulse width modulated by the pulse width modulator 13, and the data driving signal is output to the corresponding data line in accordance with the pulse width modulated additive data. The gradation controller 10 adjusts a data driving signal applied from the output circuit unit 55 to the corresponding data line according to the gradation level signal selected by the user.

In addition, the luminance adjusting unit 50 allows a user to select a desired luminance level and outputs a signal corresponding to the luminance level, and correspondingly converts a signal corresponding to the luminance level into a digital signal. A memory 53 storing the luminance data, a luminance controller 52 which senses a signal output from the luminance selector 51 and loads and outputs luminance data corresponding to the detected signal from the memory; And the adder 54 which adds and outputs the luminance data loaded and output from the memory under image control to be displayed on the display panel.

In the image processing apparatus of the present invention configured as described above, first, when a user selects a desired luminance level through the luminance selector 51, the luminance controller 50 senses the luminance level selected by the user and the luminance corresponding to the luminance level. The data is loaded from the memory 53 and output to the adder 54.

The adder 54 then adds luminance data to the image data and inputs the adder data corresponding to the result to the comparator 15, and the comparator 15 synchronizes the count bit value and the bit of the add data with the clock signal. When comparing the values and determining that the count bit value is smaller than the added data bit value, the result is output to the output circuit unit 55, and the output circuit unit 55 outputs a high level pulse signal according to the comparison result. To the corresponding data line.

On the contrary, when the comparator 15 determines that the count bit value and the added data bit value are the same or larger, the comparator 15 outputs the result to the output circuit unit 55, and the output circuit unit 55 outputs a low level pulse according to the result. A signal is applied to the corresponding data line as a data driving signal, and the comparison operation of the comparator 15 is repeatedly performed in accordance with a circulating cycle of a counting cycle.

Therefore, while the high level pulse signal is applied, the MOS field effect transistor built in the output circuit is turned on, and while the low level pulse signal is applied, the MOS field effect transistor is turned off and the corresponding unit light emitter (shown through the corresponding data line) is shown. By varying the amount of current flowing through the (not shown), the user desired brightness is expressed on the corresponding unit light emitter.

In this way, the luminance data corresponding to the luminance level selected by the user is added to the image data to be displayed on the display panel, and the pulse signal corresponding to the added luminance data is transferred to the corresponding unit emitter through the corresponding data line as the data driving signal. By being applied, the user can express the desired luminance level on the corresponding unit light emitter.

As described in detail above, the image processing apparatus of the organic light emitting display device having the luminance adjusting circuit according to the present invention includes a separate luminance adjusting circuit in the image processing apparatus to adjust the luminance of the image data according to a user's selection. By making it possible to adjust, the quality of a display image can be improved remarkably.

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 (4)

An organic electroluminescent display device for displaying an image on 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. A brightness controller which adds image data to be displayed on the display panel and brightness data corresponding to a brightness level selected by a user, and outputs additional data corresponding to the addition result; A pulse width modulator for pulse width modulating the added data output from the brightness controller; And an output circuit for outputting a data driving signal to a corresponding data line in accordance with the addition data pulse width modulated by the pulse width modulator. The apparatus of claim 1, wherein the brightness control unit; A brightness selector for allowing a user to select a desired brightness level and outputting a signal corresponding to the brightness level; A memory storing luminance data obtained by correspondingly converting the signal corresponding to the luminance level into a digital signal; A luminance controller which senses a signal output from the luminance selector and loads and outputs luminance data corresponding to the detected signal from a memory; Image processing of an organic electroluminescent display device having a brightness control circuit, comprising: an adder which adds and processes the luminance data loaded and output from a memory to be displayed on a display panel under the control of the luminance controller. Device. An organic electroluminescent display device for displaying an image on 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. A pulse width modulator for pulse width modulating and outputting image data to be displayed on the display panel according to respective gray levels; An output circuit section outputting a data driving signal to a corresponding data line according to the image data output by the pulse width modulation section outputting a pulse width; And a brightness controller configured to adjust and output a data driving signal output to the corresponding data line according to a brightness level selected by a user. 4. The apparatus of claim 3, wherein the brightness adjusting unit; A brightness selector for allowing a user to select a desired brightness level and outputting a signal corresponding to the brightness level; And a luminance controller configured to control a data driving signal applied to a corresponding data line according to the luminance level signal outputted from the luminance selector.