KR101857627B1 - Organic Light Emitting Display Device and Driving Method thereof - Google Patents

Abstract

An embodiment of the present invention relates to a display panel including RGBW subpixels; A data converter for converting the RGB data signals into RGBW data signals; An average image level calculating unit for calculating an average image level for the RGB data signal; A peak luminance controller for controlling the luminance of one or a selected frame using an average picture level and a lookup table; And generating a data signal such that the selected data signal of the RGB data signal is lighted on the display panel when the color coordinate of the W data signal is different from the target value in the RGBW data signal, The gain value of the RGB data signal with respect to the target maximum luminance average picture level is multiplied by the calculated value obtained by calculating the current average picture level and the maximum average picture level with the value of the gain of the RGB data signal with respect to the luminance average picture level, And a data compensator for calculating a correction gain value of the RGB data signal.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an organic light emitting display,

An embodiment of the present invention relates to an organic light emitting display and a driving method thereof.

An organic electroluminescent device used in an organic electroluminescent display device is a self-luminous device in which a light emitting layer is formed between two electrodes. The organic electroluminescent device injects electrons and holes from the electron injecting electrode and the hole injecting electrode into the light emitting layer, and excites the excited electrons and holes, And emits light when it is dropped to the ground state.

In the organic light emitting display, when a scan signal, a data signal, a power supply, and the like are supplied to the subpixels arranged in a matrix form, the selected subpixel emits light, thereby displaying an image.

Some of the organic light emitting display devices include a peak luminance control (PLC) controller that implements a maximum luminance by varying a gamma voltage according to an average picture level (APL) calculated for a luminance component, Lt; / RTI > The peak luminance control method is also used in organic light emitting display devices having a subpixel structure including red, green, blue, and white (hereinafter abbreviated as RGBW OLED).

However, the peak brightness control method used in conventional RGBW OLEDs uses only the red, green, and blue gains of the minimum brightness gamma without calculating gains of all the gamma-system red, green, and blue data signals (subpixels).

Therefore, the conventional RGBW OLED can not improve the brightness of the image and the problem of chromaticity shift when driving by the peak luminance control method. In the conventional peak luminance control method, since the gain used to realize the maximum luminance is realized only through actual measurement, there is a problem in that it takes a long time to implement the gain.

According to an embodiment of the present invention for solving the problems of the background art described above, a correction gain value of red, green, and blue that are turned on together to compensate for a white color coordinate is calculated using a formula, And a sub-pixel structure including red, green, blue, and white that can realize fast and accurate luminance, and a method of driving the organic light emitting display.

According to an embodiment of the present invention, there is provided a display panel including RGBW subpixels; A data converter for converting the RGB data signals into RGBW data signals; An average image level calculating unit for calculating an average image level for the RGB data signal; A peak luminance controller for controlling the luminance of one or a selected frame using an average picture level and a lookup table; And generating a data signal such that the selected data signal of the RGB data signal is lighted on the display panel when the color coordinate of the W data signal is different from the target value in the RGBW data signal, The gain value of the RGB data signal with respect to the target maximum luminance average picture level is multiplied by the calculated value obtained by calculating the current average picture level and the maximum average picture level with the value of the gain of the RGB data signal with respect to the luminance average picture level, And a data compensator for calculating a correction gain value of the RGB data signal.

The data compensator compares the current gain of the selected data signal of the RGB data signal to the maximum APL gain value of the target APL. Target Peak Lum APL RGB gain + RGB gain weight, Max APL RGB gain is the gain measured value of the RGB data signal with respect to the maximum average image level, Target Peak Lum APL RGB gain is the gain measured value of the RGB data signal with respect to the target maximum luminance average picture level, Current APL is the current average picture level, Max APL is the maximum average picture level, Target Peak Lum APL is the target maximum luminance average picture level, May be the gain weight of the RGB data signal.

The data compensator may apply a gain calculated through an equation to the GB data signal and a gain weight of the RGB data signal may be provided based on measured values of characteristics of RGB subpixels formed on the display panel.

The data compensator compares the current gain of the G data signal with a target peak Lum APL gain peak value LLAPL + (Max APL - Target Peak Lum APL) Max APL G gain is the gain measured value of the G data signal with respect to the maximum average picture level, and Target Peak Lum APL G gain is the target maximum luminance average picture level The current APL may be the current average picture level, Max APL may be the maximum average picture level, and the Target Peak Lum APL may be the average picture level of the target maximum luminance.

The data compensator calculates the current gain of the B data signal = (Max APL B gain - Target Peak Lum APL B gain) * ((Current APL - Target Peak Lum APL) / B gain and B gain weight, the Max APL B gain is the actual measured value of the B data signal with respect to the maximum average image level, and the target peak Lum APL B gain is the target maximum Max APL is the maximum average picture level, Target Peak Lum APL is the average picture level of the target maximum luminance, and B gain weight is the average value of the B data signal It may be a gain weight.

The Target Peak Lum APL may be a configurable input variable that limits the average picture level of the target maximum luminance.

The peak luminance control unit may generate a luminance control value that controls the luminance of one or a selected frame based on the correction gain value supplied from the data compensation unit.

The peak luminance control unit may supply the luminance control value to the gamma unit to set the gamma voltage.

In another aspect, an embodiment of the present invention is a data conversion method including: a data conversion step of converting an RGB data signal into an RGBW data signal; An average image level calculating step of calculating an average image level for the RGB data signal; A data generation step of generating a data signal such that a selected data signal of the RGB data signal is lighted on the display panel when the color coordinate of the W data signal is different from the target value in the RGBW data signal; And a value between the gain of the RGB data signal with respect to the maximum average picture level and the gain of the RGB data signal with respect to the target maximum luminance average picture level is multiplied by a calculated value obtained by calculating the current average picture level and the maximum average picture level, And a gain calculating step of calculating a correction gain value of the RGB data signal by adding the gain of the RGB data signal to the target maximum luminance average image level.

The gain calculation step calculates a current gain of the selected data signal of the RGB data signal = (Max APL - Target Peak Lum APL) - ((Target APL - Target Peak Lum APL) + Target Peak Lum APL RGB gain + RGB gain weight, Max APL RGB gain is the gain measured value of the RGB data signal with respect to the maximum average image level, Target Peak Lum APL RGB gain is the gain measured value of the RGB data signal for the target maximum luminance average picture level, Current APL is the current average picture level, Max APL is the maximum average picture level, Target Peak Lum APL is the target maximum luminance average picture level, and RGB The gain weight may be a gain weight of the RGB data signal.

And a luminance control step of controlling the luminance of one or a selected frame based on the correction gain value, wherein the luminance control step may set the gamma voltage by supplying the luminance control value to the gamma unit.

The gain calculation step is performed by calculating the current gain of the G data signal = (Max APL G gain - Target Peak Lum APL G gain) * ((Target APL - Target Peak Lum APL) APL G gain, Max APL G gain is the actual measured value of the G data signal with respect to the maximum average image level, and Target Peak Lum APL G gain is the target maximum luminance average image The current APL may be the current average picture level, Max APL may be the maximum average picture level, and the Target Peak Lum APL may be the average picture level of the target maximum luminance.

The gain calculation step is performed by calculating the gain of the B data signal = (Max APL B gain - Target Peak Lum APL B gain) * ((Target APL - Peak Lum APL) APL B gain + B gain weight, the maximum APL B gain is the actual measured value of the B data signal with respect to the maximum average image level, and the target peak LUM APL B gain is the target Max APL is the maximum average image level, Target Peak Lum APL is the average image level of the target maximum luminance, and B gain weight is the average value of the B data signal Lt; / RTI >

The Target Peak Lum APL may be a configurable input variable that limits the average picture level of the target maximum luminance.

The gain weight of the RGB data signal may be provided based on measured values of characteristics of RGB sub-pixels formed on the display panel.

In the embodiment of the present invention, in obtaining correction gain values of red, green, and blue that are turned on together to compensate for a white color coordinate, a large amount of gain values are not directly obtained but a fast and accurate value is found for each display panel There is an effect that can be. In addition, the embodiment of the present invention is also applicable to an organic light emitting display device having a subpixel structure including red, green, blue, and white, when the peak luminance control is driven in an organic light emitting display (abbreviated as RGBW OLED) The target color coordinates and luminance can be accurately implemented for each display panel by finding the correction gain values of red, green, and blue colors.

1 is a schematic view of an organic light emitting display device according to an embodiment of the present invention;
Fig. 2 is an exemplary circuit configuration of a subpixel. Fig.
3 is a block diagram of a scan driver;
4 is a block diagram of a data driver;
FIG. 5 is a block diagram schematically showing a main part of an organic light emitting display according to an embodiment of the present invention. FIG.
FIG. 6 is a detailed diagram of a main part of an organic light emitting display according to an embodiment of the present invention. FIG.
7 is a view for explaining a color coordinate compensation scheme according to a data compensation unit;
FIG. 8 is a view for explaining a peak luminance control method according to an embodiment method versus a comparative example method; FIG.
9 is a view for explaining the peak luminance control method according to the embodiment in detail;
10 is a graph of gradation / gain values based on the method of the comparative example and the method of the embodiment.
11 is a flowchart illustrating a method of driving an organic light emitting display according to an embodiment of the present invention.
FIGS. 12 and 13 are graphs for illustrating gain values according to the method of the embodiment with respect to actual gain values. FIG.
14 is a graph for showing a gamma curve according to an embodiment in comparison with the actual gamma curve.
FIG. 15 is a graph for showing the measured color coordinates after applying the embodiment to the color coordinates according to the direct gamma setting. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a schematic configuration diagram of an organic light emitting display according to an embodiment of the present invention, FIG. 2 is a circuit diagram of a subpixel, FIG. 3 is a block diagram of a scan driver, Block diagram.

1, an organic light emitting display according to an exemplary embodiment of the present invention includes an image processor 110, a timing controller 120, a data driver 130, a scan driver 140, and a display panel 150, .

The display panel 150 is formed of an organic light emitting display panel including subpixels (SPr, SPg, SPb, SPw) arranged in a matrix form. The subpixels SPr, SPg, SPb and SPw include a red subpixel SPr, a green subpixel SPg, a blue subpixel SPb and a white subpixel SPw, .

The sub-pixel includes a switching transistor SW, a driving transistor DR, a capacitor Cst, and an organic light emitting diode D as shown in FIG. In response to the scan signal supplied through the first scan line SL1, the switching transistor SW is supplied with the data signal supplied through the first data line SL1 to the first node n1 and is supplied to the capacitor Cst To be stored as a data voltage. The driving transistor DR operates so that the driving current flows between the first power supply terminal VDD and the second power supply terminal GND in accordance with the data voltage stored in the capacitor Cst. The organic light emitting diode D operates to emit light in accordance with the driving current generated by the driving transistor DR.

The subpixels SPr, SPg, SPb and SPw are connected to a 2T transistor 1C including a switching transistor SW, a driving transistor DR, a capacitor Cst and an organic light emitting diode D, Capacitor structure, or a structure in which transistors and capacitors are added, such as 3T1C, 4T2C, 5T2C, and the like.

The subpixels SPr, SPg, SPb and SPw having the above structure are formed in a top emission mode, a bottom emission mode or a dual emission mode depending on the structure . The red subpixel SPr, the green subpixel SPg and the blue subpixel SPb may be implemented using a color filter based on the white subpixel SPw or may be implemented using organic materials And a method of forming the color image by the corresponding color.

The image processing unit 110 receives a vertical synchronization signal, a horizontal synchronization signal, a data enable signal, a clock signal, and an RGB data signal RGB from the outside. The image processing unit 110 converts the RGB data signals RGB into RGBW data signals RGBW and supplies them to the timing control unit 120. [ The image processing unit 110 sets the gamma voltage to realize the maximum luminance according to the average image level using the RGB data signal RGB. The image processing unit 110 performs various image processes, and a detailed description thereof will be provided below.

The timing controller 120 receives a vertical synchronization signal, a horizontal synchronization signal, a data enable signal, a clock signal, and an RGBW data signal RGBW from the image processing unit 110. The timing controller 120 controls the operation timings of the data driver 130 and the scan driver 140 using timing signals such as a vertical synchronization signal, a horizontal synchronization signal, a data enable signal, and a clock signal. The timing control unit 120 can determine the frame period by counting the data enable signal of one horizontal period, so that the vertical synchronizing signal and the horizontal synchronizing signal supplied from the outside can be omitted. The control signals generated by the timing controller 120 include a gate timing control signal GDC for controlling the operation timing of the scan driver 140 and a data timing control signal DDC for controlling the operation timing of the data driver 130. [ ). The gate timing control signal GDC includes a gate start pulse, a gate shift clock, a gate output enable signal, and the like. The data timing control signal DDC includes a source start pulse, a source sampling clock, a source output enable signal, and the like.

The scan driver 140 is a gate driver that is enabled to operate the transistors of the subpixels SPr, SPg, SPb, SPw included in the display panel 150 in response to the gate timing control signal GDC supplied from the timing controller 120. [ The scan signal is sequentially generated while shifting the level of the signal by the swing width of the drive voltage. The scan driver 140 supplies the scan signals generated through the scan lines SL1 to SLm to the subpixels SPr, SPg, SPb, and SPw included in the display panel 150. [

3, the scan driver 140 includes a shift register 61, a level shifter 63, a plurality of AND gate 62 connected between the shift register 61 and the level shifter 63, An inverter 64 for inverting the enable signal GOE, and the like. The shift register 61 shifts the gate start pulse GSP sequentially in accordance with the gate shift clock GSC using a plurality of D flip-flops depending thereon. The AND gates 62 logically multiply the output signal of the shift register 61 and the inverted signal of the gate output enable signal GOE to generate an output. The inverter 64 inverts the gate output enable signal GOE and supplies it to the AND gates 62. The level shifter 63 shifts the output voltage swing width of the end gate 62 to the swing width of the scan voltage at which the transistors included in the display panel 150 are operable. The scan signal output from the level shifter 63 is sequentially supplied to the gate lines SL1 to SLm.

The data driver 130 samples and latches the RGBW data signal RGBW supplied from the timing controller 120 in response to the data timing control signal DDC supplied from the timing controller 120, Conversion. The data driver 130 converts the RGBW data signal RGBW into a digital data signal according to a gamma voltage when converting the RGBW data signal into a data signal of a parallel data format. At this time, the conversion of the digital data signal into the analog data signal is performed by a digital to analog converter (DAC) included in the data driver 130. The data driver 130 supplies the RGBW data signals RGBW converted through the data lines DL1 to DLn to the subpixels SPr, SPg, SPb, and SPw included in the display panel 150. [

The data driver 130 includes a shift register 51, a data register 52, a first latch 53, a second latch 54, a conversion unit 55, an output circuit 56, . The shift register 51 shifts the source sampling clock SSC supplied from the timing controller 120. The shift register 51 transfers the carry signal CAR to the shift register of the next source drive IC in the neighboring stage. The data register 52 temporarily stores the data signal RGBW supplied from the timing controller 120 and supplies it to the first latch 53. The first latch 53 samples and latches the data signals RGBW serially input according to the clocks sequentially supplied from the shift register 51, and outputs the latched data signals. The second latch 54 latches the data signals RGBW supplied from the first latch 53 and then synchronizes with the second latch 54 of the other source drive ICs in response to the source output enable signal SOE And outputs them at the same time. The conversion unit 55 converts the data signal RGBW input from the second latch 54 into gamma voltages GMA1 to GMAn. The data signals RGBW output from the output circuit 56 are supplied to the data lines DL1 to DLn in response to the source output enable signal SOE.

Hereinafter, an organic light emitting display according to an embodiment of the present invention will be described in more detail.

FIG. 5 is a configuration diagram briefly showing an important part of an organic light emitting display according to an embodiment of the present invention, FIG. 6 is a diagram showing a more detailed configuration of a main part of an organic light emitting display according to an embodiment of the present invention, 8 is a view for explaining a peak luminance control scheme according to an embodiment of the present invention, and FIG. 9 is a diagram for explaining a peak luminance control scheme according to an embodiment of the present invention. This is a diagram for specifically explaining the method.

5 and 6, the organic light emitting display includes an image processor 110, a timing controller 120, a data driver 130, and a gamma unit 135 .

The image processing unit 110 includes a de-gamma unit 114, a first data conversion unit 116, a data compensation unit 117, a second data conversion unit 111, an average image level calculation unit 112, And a control unit 113 are included.

The de-gamma unit 114 (De-Gamma) serves to de-gamma process the RGB data signals included in one frame. More specifically, the de-gamma unit 114 (De-Gamma) converts the received inverse gamma (D-gamma) to the RGB-data signal to prevent the bit overflow occurring during the operation of converting the RGB data signal input from the outside into the RGBW data signal Inverse Gamma) is subjected to de-gamma processing to be changed into a linear shape and bit stretching is performed. Here, the RGB data signal is changed from 10 bits (12 bits) to 12 bits (12 bits) by bit stretching by the de-gamma unit 114 and is output. The de-gamma unit 114 may perform bit stretching using a de-gamma look-up table 115. The de-

The first data converter 116 (RGB to RGBW) converts RGB data signals output through the de-gamma unit 114 into RGBW data signals. The reason why the RGB data signal is converted into the RGBW data signal by using the first data converter 116 (RGB to RGBW) is to drive the display panel including the RGBW subpixel.

The second data converter 111 (RGB to YCbCr) converts an RGB data signal supplied from the outside into a YCbCr data signal. The second data converter 111 may convert the RGB data signal into a YCbCr data signal using a conversion formula as shown in Equation 1 below.

( Equation  One)

As described above, when the RGB data signal is converted into the YCbCr data signal, the average image level calculating unit 112 can calculate the average image level based on the RGB data signal.

The average picture level calculator 112 (APL Cal) calculates an average representative value through the YCbCr data signal supplied from the second data converter 111 to calculate an average picture level (APL) . In the case of the average image level calculating section 112, the average image level can be calculated using a data signal other than the YCbCr data signal. In this case, the second data conversion unit 111 may perform or remove other methods such as a method of extracting only the maximum value of the RGB data signal without converting the RGB data signal into the YCbCr data signal. The average image level calculating unit 112 calculates the average representative value again in the Nth frame unit (e.g., 5 frames or 30 frames) so that the same average picture level is applied to a plurality of frames (a constant amount of frames) It can also be re-computed as a process. This is to prevent the flicker and the like from being accompanied by the calculation by expressing every frame. The average picture level calculating unit 112 may calculate an average picture level based on a moving picture (AVG) or may calculate an average picture level based on a scene change detection.

When the color coordinate of the W data signal is different from the target value in the RGBW data signal outputted through the first data converter 116, the data compensator 117 (LIMO) lights up the remaining RGB data signals as much as necessary, It serves to compensate for the expression. When a display panel including RGBW subpixels is used, only a W subpixel is used to represent a W image. 7, when the color coordinates of the W subpixel are different from the target value, the data compensator 117 lights up the remaining RGB data signals as much as necessary, and the RGBW data Signal (RGBW). Here, the RGBW data signal RGBW is changed from 12 bits (10 bits) to 10 bits (10 bits) by the data conversion process by the data compensator 117 and is output. The data compensator 117 compares a value between the gain of the RGB data signal with respect to the maximum average picture level and the gain of the RGB data signal with respect to the target maximum luminance average picture level, And calculates the resultant value. The data compensating unit 117 then adds the gain of the RGB data signal to the resultant value to the target maximum luminance average picture level to calculate the correction gain value Gain of the RGB data signal.

The peak luminance control section 113 includes an average picture level APL calculated from the average picture level calculating section 112, a correction gain value Gain supplied from the data compensating section 117, LIMO, 119, Optical Compensation LUT) to control the maximum luminance for each at least one frame. To this end, the peak luminance controller 113 generates a luminance control value plcc for controlling the luminance of one or a selected frame based on the correction gain value supplied from the data compensator 117. The peak luminance controller 113 supplies the luminance control signal value plc to the gamma unit 135 (P-Gamma) that provides a gamma voltage to the data driver 130 (SD-IC) And controls the maximum luminance. Here, the lookup table 119 may use internal or external memory such as "EEPROM" in which the optically compensated data signal is stored. The gamma unit 135 may use programmable gamma capable of changing the gamma voltage (or the gamma curve) corresponding to the brightness control value plcc supplied from the peak brightness control unit 113. [

On the other hand, the data compensator 117 calculates the correction gain value Gain through a formula expressed by the following equation (2) for the current gain of the selected data signal among the RGB data signals.

( Equation  2)

The current gain of the data signal = (Max APL RGB gain - Target Peak Lum APL RGB gain) * (Target APL - Target Peak Lum APL) + Target Peak Lum APL RGB gain + RGB gain weight

Here, Max APL RGB gain is the gain measured value of the RGB data signal with respect to the maximum average picture level, Target Peak Lum APL RGB gain is the measured actual value of the RGB data signal with respect to the target maximum luminance average picture level, Current APL is the current average picture level, Max APL is the maximum average image level, Target Peak Lum APL is the target maximum luminance average image level, and RGB gain weight is the gain weight of the RGB data signal.

The data compensating section 117 applies the gain calculated by equation (2) to the GB data signal in particular. In this regard, in the case of the R subpixel formed on the display panel, the efficiency is superior to the other GB subpixels. Therefore, the R data signal may not generate a separate correction gain value. Instead, when a separate correction gain value calculation for the R data signal is required, it is possible to use a formula for calculating the correction gain value of the G data signal. On the other hand, in the case of the B subpixel formed on the display panel, the efficiency is lower than that of the other RG subpixels, so that the ratio of the enhancement increases nonlinearly toward the low / high gray level. Therefore, in the case of the B data signal, the gain weight of the B data signal is further included in Equation (2), and the gain weight of the B data signal is prepared based on the measured value of the characteristics of the B subpixel formed on the display panel. That is, the gain weight of the B data signal may vary depending on the characteristics of the device. In addition, the gain weight provided based on the measured values obtained by measuring the characteristics of the RG data signal and the RG data signal can be further added, but is usually added as "0 ". This is because the efficiency of the RG subpixel lit on the display panel is higher than the efficiency of the B subpixel. However, if the efficiency of the RG subpixels is different, these also add to the gain weight.

Meanwhile, with reference to the method (b) of the embodiment in comparison with the method (a) of the comparative example of FIG. 8, a description of the correction gain value calculation of the data compensator 117 will be described as follows.

First, in the method (a) of the comparative example, in order to set the maximum luminance (peak luminance) to be controlled based on the average picture level, gain measurement for each point from the first point P1 to the nth point Pn must be performed do. That is, the gain should be obtained from the actual measured value of the RGB data signal for the maximum luminance gamma to the actual measured value of the RGB data signal for the minimum luminance gamma. And gain portions other than the measurement points (P1 to Pn) must be linearly processed. Therefore, when the method (a) of the comparative example is used, the loss of the measurement time due to the fact that all the gain values should be based on the measured values follows.

On the other hand, the method (b) of the embodiment performs gain measurement only for the first point P1 and the second point Pn or more to set the maximum luminance (peak luminance) based on the average picture level . That is, only the actual measured value of the RGB data signal with respect to the actual measured value of the RGB data signal with respect to the maximum average image level and the target maximum luminance average image level can be obtained. Then, the gains other than the measurement points (P1, Pn) are calculated as the correction gain value (Gain) through Equation (2). Therefore, using the method (b) of the embodiment, the loss of the measurement time is minimized since it is based on the measured value of the gain of two points.

Therefore, by using the above equation, the gain of the R data signal, the gain of the G data signal, and the gain of the B data signal are obtained, and the maximum luminance of the peak luminance controller 113 can be easily controlled based on the gains.

On the other hand, the data compensation unit 117 may configure the correction gain value Gain of the RGB data signal to be an FPGA and an ASIC-converted IC. Therefore, the method (b) of the embodiment can calculate the correction gain value Gain in real time and control the maximum luminance of the peak luminance controller 113 based on the correction gain value Gain. Since the image data is digitized by an external optical compensating device, it is possible to use a method of recording in a memory (EEPROM) storing a storage device such as an FPGA, an ASIC IC or an image processing unit 110, such as an optical compensation LUT It is possible.

As described above, the method (b) of the embodiment provides the gain value of the W data signal according to each average image level value. The method (b) of the embodiment is a method in which the gain of the RGB data signal with respect to the maximum average picture level obtained through the measurement and the gain of the RGB data signal with respect to the target maximum luminance average picture level are increased .

According to the above description, the data compensator 117 calculates the current gain of the G data signal (or R data signal), that is, the corrected gain value, based on the average picture level of the target maximum luminance through the following equation can do.

( Equation  3)

G data signal current gain = (Max APL G gain - Target Peak Lum APL G gain) * ((APL - Target Peak Lum APL) + Target Peak Lum APL G gain

Where Max APL G gain is the gain measured value of the G data signal with respect to the maximum average image level, Target Peak Lum APL G gain is the gain measured value of the G data signal with respect to the target maximum luminance average picture level, Current APL is the current average picture level, Max APL is the maximum average picture level and Target Peak Lum APL is the average picture level of the target maximum luminance.

As can be seen from the above equation (3), when the target maximum luminance average picture level is subtracted from the current average picture level and the maximum average picture level in the equation (2), correction of the G data signal according to the average picture level of the target maximum luminance The gain value Gain can be calculated. Therefore, the Target Peak Lum APL in Fig. 9 becomes a setter input variable for limiting the average picture level of the target maximum luminance to a percentage of the maximum average picture level (Max APL).

Further, according to the above description, the data compensator 117 can calculate the current gain of the B data signal, that is, the correction gain value, based on the average picture level of the target maximum luminance through the following equation (4).

( Equation  4)

B data signal = (Max APL B gain - Target Peak Lum APL B gain) * ((APL - Target Peak Lum APL) + Target Peak Lum APL B gain + B gain weight

Where Max APL B gain is the gain measured value of the B data signal with respect to the maximum average picture level, Target Peak Lum APL B gain is the measured actual value of the B data signal with respect to the target maximum luminance average picture level, Current APL is the current average picture level, Max APL is the maximum average picture level, Target Peak Lum APL is the average picture level of the target maximum luminance, and B gain weight is the gain weight of the B data signal.

As can be seen from Equation (4), if the average picture level of the target maximum luminance is subtracted from the current average picture level and the maximum average picture level of Equation (2), the B data signal It is possible to calculate the correction gain value Gain. Therefore, the Target Peak Lum APL in Fig. 9 becomes a setter input variable for limiting the average picture level of the target maximum luminance to a percentage of the maximum average picture level (Max APL).

On the other hand, not only the gain weight for the B data signal but also the RG data signal and the gain weight can be further added. In the case of the gain weight, it can be used as a value extracted by the first-order equation using the difference between the gain value of the actual average image level of the subpixels and the calculated gain value. This value is usually determined by the luminance efficiency of the device used in the subpixel and can be extracted by direct measurement of the device. As a method of extracting the gain weight, a linear equation can be obtained by using the difference between the actual gain value and the calculated gain value of 10 points (10, 20, 30 to 80, 90, 100) for each average image level. Here, the gain weight value for each RGB becomes closer to zero as the average image level and the gain value are proportional to each other.

A concrete example of the method (a) of the comparative example and the method (b) of the embodiment described above is as follows.

10 is a grayscale / gain value graph based on the method of the comparative example and the method of the embodiment. 10 shows the grayscale / gain values for the correction gain value (Green gain) of the G data signal and the correction gain value (Blue gain) of the B data signal.

Table 1 and Table 2 below show correction gain values (Table 2) using the correction gain values (Table 1) using the method (a) and the correction gain values (Table 2) of the embodiment when the average image level (APL) is 43.75% .

The correction gain values (G gain, B gain) 29 and 127 of the G and B data signals in the equation of Table 2 are calculated in the following manner.

The current gain of the G data signal = (51 - 22) * ((43.75 - 25) / (100 - 25)) + 22 + 0 = 29.25

B current data signal gain = (153 - 99) * ((43.75 - 25) / (100 - 25)) + 99 + 15.14825 = 127.64825

Here, 15.14825 is a gain weight of the B data signal, and based on the measured value of the B subpixel formed on the display panel, the calculated weight value of the B data signal is -0.245 (43.75) + 25.867 = 15.14825.

As can be seen from Tables 1 and 2 and FIG. 10, the gain of the measured value according to the method (a) of the comparative example and the gain of the formula according to the method (b) of the embodiment show similar gradation. As can be seen from this, it can be seen that the method using the method (b) of the embodiment is able to display similar or same gradation to the actual measurement even if the actual measurement is not performed for all the points.

Therefore, in the method (b) of the embodiment, the correction gain values of red, green, and blue that are turned on together to compensate for the white color coordinates are calculated by using a formula so that desired target color coordinates and luminance can be quickly and accurately implemented for each display panel do.

Hereinafter, a driving method of an organic light emitting display according to an embodiment of the present invention will be described.

11 is a flowchart illustrating a method of driving an organic light emitting display according to an exemplary embodiment of the present invention.

Hereinafter, the embodiments will be described with reference to FIGS. 1 to 11 described above.

The driving method of an organic light emitting display according to an exemplary embodiment of the present invention includes a data conversion step S111, an average image level calculation step S113, a data signal generation step S114, a correction gain value calculation step S115, A control value generation step S119, a gamma voltage setting step S121, and an image display step S123.

When the RGB data signal RGB is supplied through the image processing unit 110, the first data conversion unit 116 performs a data conversion step S111 for converting the RGB data signals RGB into RGBW data signals RGBW .

The average image level calculating section 112 performs an average image level calculating step S113 for calculating an average image level APL for the RGB data signals RGB.

The data compensating unit 117 corrects the data signal so that the selected data signal of the RGB data signal RGB is lighted on the display panel 150 when the color coordinate of the W data signal W is different from the target value in the RGBW data signal RGBW (S114). ≪ / RTI >

In addition, the data compensating section 117 computes the current average image level and the maximum average image level to the value between the gain of the RGB data signal for the maximum average image level and the gain of the RGB data signal for the target maximum luminance average image level And the result is multiplied by an operation value. Then, a gain calculating step S115 for calculating a correction gain value Gain of the RGB data signal by adding the gain of the RGB data signal to the resultant value to the target maximum luminance average image level is performed.

The gain calculation step S115 calculates the gain of the selected data signal among the RGB data signals RGB = (Max APL RGB gain - Target Peak Lum APL RGB gain) * ((Current APL - Target Peak Lum APL) / Target Peak Lum APL) + Target Peak Lum APL RGB gain + RGB gain weight based on the calculated gain.

In this case, the data compensator 117 compares the current gain of the G data signal = (Max APL G gain - Target Peak Lum APL G gain) * ((Current APL - Target Peak Lum APL) / (Max APL - ) + Target Peak Lum APL The correction gain value of the G data signal is calculated through a formula expressed by G gain.

In addition, the data compensator 117 compares the current gain of the B data signal = (Max APL B gain - Target Peak Lum APL B gain) * ((Current APL - Target Peak Lum APL) / ) + Target Peak Lum APL B gain + B gain weight (S117).

Here, the Target Peak Lum APL becomes a setter input variable for limiting the average picture level of the target maximum luminance. The gain weight of the B data signal is provided based on measured values obtained by measuring the characteristics of the B subpixel SPb formed on the display panel 150. [

The data compensator 117 supplies the correction gain value Gain of the selected data signal among the RGB data signals RGB to the peak luminance controller 113. [ The peak luminance controller 113 generates a luminance control value plcc to control the luminance of one or a selected frame based on the correction gain value Gain supplied from the data compensator 117 ).

The peak luminance control section 113 supplies the luminance control value plcc to the gamma section 135. [ The gamma unit 135 performs a gamma voltage setting step S121 for setting a gamma voltage based on the luminance control value plcc supplied from the peak luminance controller 113. [ The data driver 130 maps the RGBW data signal RGBW supplied from the timing controller 120 based on the gamma voltage and supplies the RGBW data signal RGBW to the display panel 150.

The display panel 150 performs an image display step S123 of displaying an image based on the RGBW data signal RGBW mapped to the gamma voltage set by the gamma unit 135. [ With the above process, the display panel 150 displays an image in which the color coordinate is corrected and the maximum luminance is controlled.

FIGS. 12 and 13 are graphs for showing gain values according to the method of the embodiment with respect to the actual gain values. 12 and 13, the X-axis represents the gray level and the Y-axis represents the luminance.

12 and 13, the correction gain value (e.g., Current Luminance Calculated Green Gain) of the GB data signal calculated according to the method (b) of the embodiment is measured according to the method (a) (For example, Current Luminance Real Blue Gain) of the GB data signal that has been obtained by the comparison.

On the other hand, the reason why the difference between the correction gain value of the B data signal such as 63 gradation and 31 gradation is caused by the limit of the device. Therefore, the method (b) of the embodiment can calculate the correction gain value to a similar or the same value without a large error other than the error caused by the device limit.

FIG. 14 is a graph for showing a gamma curve according to an embodiment in comparison with a gamma curve according to actual measurement, and FIG. 15 is a graph for showing the color coordinates measured after applying the embodiment of the present invention with respect to a color coordinate according to direct gamma setting. In Fig. 14, the X-axis represents the gradation and the Y-axis represents the luminance. In Fig. 15, the X-axis represents the gradation and the Y-axis represents the color coordinate.

As shown in Figs. 14 and 15, the luminance (Current Luminance Calculate Gamma) and the color coordinates (measured X and Y coordinates after applying the formula) obtained by applying the correction gain value of the RGB data signal calculated according to the method (b) (Current Luminance Real Gamma) and the color coordinates (direct gamma setting X, Y coordinates) of the corrected RGB data signal measured according to (a).

Therefore, the method (b) of the embodiment can obtain and apply the correction gain value of the desired RGB data signal through the above-described equation without setting (correcting) the correction gain value of the direct RGB data signal. In addition, the method (b) of the embodiment can obtain accurate luminance and color coordinates as compared with the conventional maximum luminance control method.

As described above, when the data signal is generated so that the selected data signal is lit on the display panel and the correction gain value of the RGB data signal is calculated using the formula, the RGB data signal Can be obtained.

In the embodiment of the present invention, in order to obtain correction gain values of red, green, and blue that are turned on together to compensate for a white color coordinate, a large amount of gain values are not directly obtained, There is an effect that can be found. In addition, the embodiment of the present invention is also applicable to an organic light emitting display device having a subpixel structure including red, green, blue, and white, when the peak luminance control is driven in an organic light emitting display (abbreviated as RGBW OLED) The target color coordinates and luminance can be accurately implemented for each display panel by finding the correction gain values of red, green, and blue colors.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood that the invention may be practiced. It is therefore to be understood that the embodiments described above are to be considered in all respects only as illustrative and not restrictive. In addition, the scope of the present invention is indicated by the following claims rather than the detailed description. Also, all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included within the scope of the present invention.

110: image processor 120: timing controller
130: Data driver 140:
150: Display panel 135: Gamma part
116: first data conversion unit 117: data compensation unit
111: second data conversion unit 112: average image level calculation unit
113: peak luminance control section

Claims (16)

A display panel including RGBW subpixels;
A data converter for converting the RGB data signals into RGBW data signals;
An average image level calculating unit for calculating an average image level for the RGB data signal;
A peak luminance controller for controlling the luminance of one or a selected frame using the average picture level and the lookup table; And
A data signal is generated so that a selected data signal among the RGB data signals is lighted on the display panel when a color coordinate of the W data signal is different from a target value in the RGBW data signal, A value obtained by multiplying the value of the gain of the RGB data signal with respect to the target maximum luminance average image level by a calculated value obtained by calculating the current average image level and the maximum average image level, And a data compensator for calculating a correction gain value of the RGB data signal by adding the gain of the RGB data signal. The method according to claim 1,
The data compensation unit
The current gain of the selected data signal of the RGB data signal is calculated as follows: Max APL RGB gain Target Peak Lum APL RGB gain * ((Current APL - Target Peak Lum APL) / (Max APL - Target Peak Lum APL) Lum APL RGB gain + RGB gain weight, the correction gain value is calculated based on the gain calculated through the equation,
Wherein the maximum APL RGB gain is a gain measured value of the RGB data signal with respect to the maximum average picture level, the target peak Lum APL RGB gain is a measured gain value of the RGB data signal with respect to the target maximum luminance average picture level, Wherein the Max APL is a maximum average picture level, the Target Peak Lum APL is a target maximum luminance average picture level, and the RGB gain weight is a gain weight of the RGB data signal. 3. The method of claim 2,
The data compensation unit
Applying a gain calculated through the above equation to the GB data signal,
Wherein the gain weight of the RGB data signal is provided based on measured values of characteristics of RGB sub-pixels formed on the display panel. The method according to claim 1,
The data compensation unit
G data signal current gain = Max APL G gain - Target Peak Lum APL G gain * ((Current APL - Target Peak Lum APL) / (Max APL - Target Peak Lum APL) A correction gain value of the G data signal is calculated through an expression represented,
Wherein the maximum APL G gain is a gain measured value of the G data signal with respect to the maximum average picture level, the target peak Lum APL G gain is a measured actual value of the G data signal with respect to the target maximum luminance average picture level, Wherein the maximum APL is the maximum average image level, and the Target Peak Lum APL is the average image level of the target maximum luminance. The method according to claim 1,
The data compensation unit
B data signal = (Max APL B gain - Target Peak Lum APL B gain) * ((APL - Target Peak Lum APL) + Target Peak Lum APL B gain + B gain weight of the B data signal through an expression represented by B gain weight,
The maximum APL B gain is the actual measured value of the B data signal with respect to the maximum average picture level, the target peak Lum APL B gain is the measured actual value of the B data signal with respect to the target maximum luminance average picture level, Wherein the Max APL is the maximum average picture level, the Target Peak Lum APL is the average picture level of the target maximum luminance, and the B gain weight is a gain weight of the B data signal. . The method according to claim 4 or 5,
The Target Peak Lum APL
And a setter input parameter for limiting an average picture level of the target maximum luminance. The method according to claim 1,
The peak luminance controller
And generates a luminance control value for controlling the luminance of the one or the selected frame based on the corrected gain value supplied from the data compensating unit. 8. The method of claim 7,
The peak luminance controller
And the gamma unit supplies the luminance control value to set the gamma voltage. [Claim 9 is abandoned upon payment of registration fee.] A data conversion step of converting an RGB data signal into an RGBW data signal;
An average image level calculating step of calculating an average image level for the RGB data signal;
A data generating step of generating a data signal so that a selected data signal among the RGB data signals is lighted on a display panel when a color coordinate of the W data signal is different from a target value in the RGBW data signal; And
A value between the gain of the RGB data signal with respect to the maximum average image level and the gain between the RGB data signal with respect to the target maximum luminance average image level is multiplied by a calculation value obtained by computing the current average image level and the maximum average image level, And a gain calculating step of calculating a correction gain value of the RGB data signal by adding a gain of the RGB data signal to the target maximum luminance average picture level. [Claim 10 is abandoned upon payment of the registration fee.] 10. The method of claim 9,
The gain calculating step
The current gain of the selected data signal of the RGB data signal is calculated as follows: Max APL RGB gain Target Peak Lum APL RGB gain * ((Current APL - Target Peak Lum APL) / (Max APL - Target Peak Lum APL) Lum APL RGB gain + RGB gain weight, the correction gain value is calculated based on the gain calculated through the equation,
Wherein the maximum APL RGB gain is a gain measured value of the RGB data signal with respect to the maximum average picture level, the target peak Lum APL RGB gain is a measured gain value of the RGB data signal with respect to the target maximum luminance average picture level, Wherein the Max APL is a maximum average picture level, the Target Peak Lum APL is a target maximum luminance average picture level, and the RGB gain weight is a gain weight of the RGB data signal. . [Claim 11 is abandoned upon payment of the registration fee.] 10. The method of claim 9,
And a luminance control step of controlling luminance of one or a selected frame based on the correction gain value,
Wherein the luminance control step sets the gamma voltage by supplying the luminance control value to the gamma unit. [12] has been abandoned due to the registration fee. 10. The method of claim 9,
The gain calculating step
G data signal current gain = Max APL G gain - Target Peak Lum APL G gain * ((Current APL - Target Peak Lum APL) / (Max APL - Target Peak Lum APL) A correction gain value of the G data signal is calculated through an expression represented,
Wherein the maximum APL G gain is a gain measured value of the G data signal with respect to the maximum average picture level, the target peak Lum APL G gain is a measured actual value of the G data signal with respect to the target maximum luminance average picture level, Wherein the Max APL is the maximum average image level, and the Target Peak Lum APL is an average image level of the target maximum luminance. [13] has been abandoned due to the registration fee. 10. The method of claim 9,
The gain calculating step
B data signal = (Max APL B gain - Target Peak Lum APL B gain) * ((APL - Target Peak Lum APL) + Target Peak Lum APL B gain + B gain weight of the B data signal through an expression represented by B gain weight,
The maximum APL B gain is the actual measured value of the B data signal with respect to the maximum average picture level, the target peak Lum APL B gain is the measured actual value of the B data signal with respect to the target maximum luminance average picture level, Wherein the Max APL is the maximum average picture level, the Target Peak Lum APL is the average picture level of the target maximum luminance, and the B gain weight is a gain weight of the B data signal. . [14] has been abandoned due to the registration fee. The method according to claim 12 or 13,
The Target Peak Lum APL
Wherein the set value is a setter input parameter for limiting an average picture level of the target maximum luminance. [Claim 15 is abandoned upon payment of registration fee] 14. The method of claim 13,
Wherein the gain weight of the RGB data signal is provided based on measured values of characteristics of RGB sub-pixels formed on the display panel. The method according to claim 1,
The display panel
W, the selected one or more of the RGB sub-pixels are further turned on.

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