KR102034051B1 - Curved flat display device and method for driving the same - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a curved flat panel display device and a method of driving the same, which improve image display quality and reliability thereof by correcting the correlated color temperature according to the viewing angle of the curved flat panel display device. A curved display panel formed with a plurality of pixel regions; A power supply unit applying first and second power signals to power lines of the curved display panel; The digital image data is displayed by storing the central color temperature correction coefficient and the upper and lower color temperature correction coefficients of the curved display panel, respectively, and converting the gamma voltage level by using the central and upper and lower color temperature correction coefficients. And a driving integrated circuit configured to convert an analog data voltage to compensate for a correlated color temperature, and display an image based on the data voltage compensated for by the correlated color temperature on the curved display panel.

Description

CURVED FLAT DISPLAY DEVICE AND METHOD FOR DRIVING THE SAME}

The present invention relates to a curved flat panel display and a driving method thereof, which improves image display quality and reliability thereof by correcting the correlated color temperature so as not to be distorted according to the viewing angle of the curved flat panel display. .

Recently, flat panel displays are emerging as liquid crystal displays, field emission displays, plasma display panels, and organic light emitting diode displays. Emitting Diode Display). Among them, the organic light emitting diode display has high luminance, low driving voltage, and ultra-thin film, which is usefully applied to mobile communication devices such as smart phones and tablet pads.

Each of the pixels constituting the organic light emitting diode display includes an organic light emitting diode (OLED) pixel including an organic light emitting layer between an anode and a cathode, a pixel circuit driving each OLED pixel independently, and a pixel circuit driving each pixel circuit. A drive control circuit is provided. Such an organic light emitting diode display converts digital data into an analog image signal (current or voltage signal) using a gamma voltage for each gray level, and supplies the converted image signals to respective pixel circuits to provide an image through each OLED pixel. Should be displayed.

Recently, since an organic light emitting diode display using a self-luminous element is easily applied to a curved flat panel display, such an organic light emitting diode display is mainly developed and commercialized as a curved flat panel display. However, the conventional flat panel display device manufactured in a curved shape has a larger viewing angle change unlike a general flat panel display device, resulting in a problem that different color characteristics are displayed according to the viewing angle change. Therefore, in the case of curved flat panel display devices, a technique for preventing a correlation color temperature from being distorted according to a viewing angle is required to be additionally applied and developed, unlike a general flat panel display device.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and the curved display is designed to improve the image display quality and its reliability by correcting the correlated color temperature so as not to be distorted according to the viewing angle of the curved flat panel display. It is an object of the present invention to provide a flat panel display and a driving method thereof.

In accordance with another aspect of the present invention, an organic light emitting diode display device includes: a curved display panel including a plurality of pixel areas; A power supply unit applying first and second power signals to power lines of the curved display panel; The digital image data is displayed by storing the central color temperature correction coefficient and the upper and lower color temperature correction coefficients of the curved display panel, respectively, and converting the gamma voltage level by using the central and upper and lower color temperature correction coefficients. And a driving integrated circuit configured to convert an analog data voltage to compensate for a correlated color temperature, and display an image based on the data voltage compensated for by the correlated color temperature on the curved display panel.

The driving integrated circuit controls driving timing of gates and data lines of the curved display panel, sets a gamma voltage level, and outputs the digital image data in alignment with driving of the curved display panel. A controller to generate correction data for correcting the gamma voltage level according to the display position of each horizontal line of the digital image data by interpolation using a central color temperature correction coefficient and an upper / lower color temperature correction coefficient of the curved display panel; An output gamma voltage controller and a gamma voltage set by subdividing a reference gamma voltage so as to correspond to a gray value of the digital image data in response to a gamma selection signal from the timing controller, and generating at least one horizontal line according to the correction data The voltage of the gamma voltage set in units A gamma voltage generator for modulating and outputting a bell, and a digital-analog conversion for converting and outputting one horizontal line of digital image data into an analog data voltage using a gamma voltage set modulated by at least one horizontal line. It is characterized by having a part.

The gamma voltage controller includes correction coefficients for correcting the gamma voltage level according to the display position of the digital image data for each of the upper and lower ends of the curved display panel using the interpolation methods shown in Equations 1 and 2 below. Generating the correction data,

[Equation 1]

Upper part correction data (Idata) = GM-(GM-CM) × each horizontal line / (B × 2)

[Equation 2]

Lower part correction data (Idata) = CM-(GM-CM) × each horizontal line / (B × 2)

GM is a central color temperature correction coefficient, CM is an upper / lower color temperature correction coefficient, and B is a number of horizontal lines (or horizontal line resolution).

The correction data includes correction coefficients for converting the average voltage level, the maximum voltage level, or at least one gamma voltage level of the gamma voltage set, and the closer the upper and lower portions of the curved display panel, the larger the correction coefficients are. As the closer to the center, the correction coefficients are set to be smaller, so that the color temperature compensation degree of the digital image data displayed at the upper and lower parts becomes larger, and the color temperature compensation degree of the digital image data displayed closer to the center is smaller. It is characterized by one.

The gamma voltage controller receives and stores the central color temperature correction coefficient and the upper and lower color temperature correction coefficients of the curved display panel for each of red, green, and blue, and stores the central color temperature correction coefficient for each of the red, green, and blue colors. The interpolation method using the upper / lower color temperature correction coefficients generates and outputs the correction data of each of red, green, and blue colors to correct the gamma voltage levels of red, green, and blue according to the display position of each horizontal line of the digital image data. Characterized in that.

In addition, the driving method of the organic light emitting diode display according to the embodiment of the present invention for achieving the above object comprises the steps of applying the first and second power signal to the power line of the curved display panel; The digital image data is displayed by storing the central color temperature correction coefficient and the upper and lower color temperature correction coefficients of the curved display panel, respectively, and converting the gamma voltage level by using the central and upper and lower color temperature correction coefficients. Converting to an analog data voltage such that a correlation color temperature is compensated for; And displaying an image by an analog data voltage having the correlation color temperature compensated on the curved display panel.

Converting the analog data voltage to compensate for the correlated color temperature sets a gamma voltage level, aligns and outputs the digital image data according to driving of the curved display panel, and a central color of the curved display panel. Generating and outputting correction data for correcting the gamma voltage level according to the display position of each horizontal line of the digital image data by interpolation using a temperature correction coefficient and an upper / lower color temperature correction coefficient, and responding to the gamma selection signal. Generating a gamma voltage set by subdividing a reference gamma voltage so as to correspond to grayscale values of the digital image data, and modulating and outputting a voltage level of the gamma voltage set in units of at least one horizontal line according to the correction data; And input modulated in at least one horizontal line unit And converting the digital image data of one horizontal line into an analog data voltage and outputting the same by using the gamma voltage set.

Generating and outputting the correction data may be performed such that the gamma voltage level is corrected according to the display position of the digital image data for each of the upper and lower portions of the curved display panel using the interpolation method shown in Equations 1 and 2 below. Generating the correction data including the correction coefficients

[Equation 1]

Upper part correction data (Idata) = GM-(GM-CM) × each horizontal line / (B × 2)

[Equation 2]

Lower part correction data (Idata) = CM-(GM-CM) × each horizontal line / (B × 2)

GM is a central color temperature correction coefficient, CM is an upper / lower color temperature correction coefficient, and B is a number of horizontal lines (or horizontal line resolution).

The correction data includes correction coefficients for converting the average voltage level, the maximum voltage level, or at least one gamma voltage level of the gamma voltage set, and the closer the upper and lower portions of the curved display panel, the larger the correction coefficients are. As the closer to the center, the correction coefficients are set to be smaller, so that the color temperature compensation degree of the digital image data displayed at the upper and lower parts becomes larger, and the color temperature compensation degree of the digital image data displayed closer to the center is smaller. It is characterized by one.

The generating and outputting of the correction data may include storing central color temperature correction coefficients and upper and lower color temperature correction coefficients of red, green, and blue, respectively, and storing the central color temperature correction coefficients of the curved display panel. The correction of each of the red, green and blue gamma voltage levels is corrected according to the display position of each horizontal line of the digital image data by interpolation using a color temperature correction coefficient and an upper / lower color temperature correction coefficient. And generating and outputting data.

According to an exemplary embodiment of the present invention, the curved flat panel display and the driving method thereof convert the gamma voltage level according to the display position of the digital image data, thereby converting the digital image data to compensate for the correlated color temperature. Can be converted to data voltage. In this way, by correcting the correlated color temperature so as not to be distorted according to the viewing angle of the curved flat panel display, the image display quality and its reliability can be improved.

1 is a circuit diagram illustrating a curved organic light emitting diode display device color temperature correction device according to an exemplary embodiment of the present invention.
FIG. 2 is a schematic diagram illustrating a curved organic light emitting diode display and a color temperature correcting apparatus illustrated in FIG. 1.
FIG. 3 is a diagram illustrating the driving integrated circuit of FIG. 1 in detail.
FIG. 4 is a graph for explaining a method of generating correction data of the gamma voltage controller shown in FIG. 3. FIG.
5A through 5C are other graphs for describing a method of generating correction data of the gamma voltage controller shown in FIG. 3.

Hereinafter, a curved flat panel display and a driving method thereof according to an embodiment of the present invention having the above characteristics will be described in detail with reference to the accompanying drawings.

The flat panel display device that can be applied to the curved flat panel display device includes a liquid crystal display, a field emission display, a plasma display panel, and an organic light emitting diode display device. Organic Light Emitting Diode Display) may be applied. However, hereinafter, an example in which the organic light emitting diode display is applied as a curved flat panel display will be described.

1 is a configuration circuit diagram illustrating a color temperature correcting apparatus of a curved organic light emitting diode display according to an exemplary embodiment of the present invention. FIG. 2 is a schematic diagram illustrating the curved organic light emitting diode display and the color temperature correcting apparatus of FIG. 1.

1 and 2, the curved organic light emitting diode display includes a curved display panel 1 including a plurality of pixel regions; A power supply unit 4 for applying first and second power signals VDD and GND to power lines PLn to PLm of the curved display panel; The central color temperature correction coefficient GM and the upper and lower color temperature correction coefficients CM are respectively stored in the curved display panel 1, and the gamma voltage is applied using the central and upper and lower color temperature correction coefficients GM and CM, respectively. By converting the level by itself, the digital image data RGB is converted into an analog data voltage so that a correlated color temperature is compensated according to its display position, and the curved display panel 1 displays an image with the data voltage compensated for by the correlated color temperature. A driving integrated circuit 2 is provided.

Here, the driving integrated circuit 2 receives and stores the central and upper and lower color temperature correction coefficients GM and CM of the curved display panel 1 from the color temperature correction device. As shown in FIG. 2, the color temperature correction device is input from the color temperature detector 5 and the color temperature detector 5 respectively detecting the central color temperature and the upper / lower color temperature of the curved display panel 1. Color temperature correction supplied to the driving integrated circuit 2 by setting the central and upper / lower color temperature correction coefficients GM and CM of the curved display panel 1 according to the color temperature CTn of the respective positions. The control unit 4 is provided. Here, the center color temperature correction coefficient GM and the upper and lower color temperature correction coefficients CM may be the average voltage level or the maximum voltage level or at least one gamma voltage of the gamma voltage set that is set and generated in the driving integrated circuit 2. Coefficient for converting levels.

In the image display panel 1, a plurality of sub-pixels P are arranged in a matrix form in each pixel area to display an image, and each sub-pixel P is an organic light emitting diode and an organic light emitting diode. A diode driving circuit for independently driving a light emitting diode is provided. Specifically, one sub-pixel P is disposed between a diode driving circuit connected to any one of the gate line GL, the data line DL, and the power supply line PL, between the diode driving circuit and the second power signal GND. A connected light emitting diode is provided. Here, the diode driving circuits supply the analog image signals from the connected data lines DL1 to DLm to the organic light emitting diodes while charging the supplied analog image signals to maintain the light emitting state.

The driving integrated circuit 2 generates at least one sync signal by itself to generate gate control signals for driving the gate lines GL1 to GLn, and uses the gate-on signal (eg, low or high). Logic gate voltages) are generated and output sequentially. The pulse width of the gate on signal is controlled to sequentially supply the gate on signals to the gate lines GL1 to GLn. Here, a gate-off voltage (eg, a high logic gate voltage) is supplied to a period when the gate-on voltage is not supplied to the gate lines GL1 to GLn. Accordingly, the driving integrated circuit 2 causes the diode driving circuits connected to the gate lines GL1 to GLn to be driven in units of the gate line GL.

The driving integrated circuit 2 stores the central and upper and lower color temperature correction coefficients GM and CM of the curved display panel 1 supplied from the color temperature correction device. The interpolation method using the central color temperature correction coefficient GM and the upper and lower color temperature correction coefficients CM generates correction data for correcting the gamma voltage level for each display position of the image data RGB. Accordingly, the driving integrated circuit 2 converts the gamma voltage level for each display position of the digital image data RGB according to the correction data, thereby compensating the correlated color temperature of the digital image data RGB according to the display position, thereby analog data. Allow to convert to voltage. The analog data voltage thus converted is supplied to each data line DL1 through DLm by one horizontal line every one horizontal period. The driving integrated circuit 2 according to the present invention will be described in more detail later with reference to the drawings.

The power supply 3 supplies the first power signal VDD and the second power signal GND to the image display panel 1. Here, the first power signal VDD means a driving voltage for driving the light emitting diodes, and the second power signal GND may mean a ground voltage or a low voltage. Due to the difference between the first power signal VDD and the second power signal GND, a current corresponding to an image signal may also flow in each sub-pixel P. FIG.

FIG. 3 is a diagram illustrating in detail the driving integrated circuit illustrated in FIG. 1.

The driving integrated circuit 2 shown in FIG. 3 controls the driving timing of the gate and data lines GL1 to GLn and DL1 to DLm, sets the gamma voltage level, and curves the digital image data RGB. Interpolation method using timing control unit 21 for outputting the alignment according to driving of display panel 1, color temperature correction coefficient GM in the center of curved display panel 1, and upper and lower color temperature correction coefficients CM. The gamma selection signal from the gamma voltage controller 28 and the timing controller 21 for generating and outputting correction data Idata for correcting the gamma voltage level according to the display position for each horizontal line of the digital image data RGB In response to VREG, a gamma voltage set is generated by subdividing the reference gamma voltage so as to correspond to the grayscale values of the digital image data RGBs, and generating the gamma voltage set in at least one horizontal line unit according to the correction data Idata. Digital image data (RData) for one horizontal line using a gamma voltage generator 26 for modulating and outputting a set voltage level and a gamma voltage set MV0 to MV255 that is modulated and input in units of at least one horizontal line. A digital-to-analog converter (DAC) 25 converts the data into an analog data voltage AData.

In addition, the driving integrated circuit 2 may include the timing of the gate driver 22 sequentially supplying the gate-on signal Vscan to the gate lines GL1 to GLn according to the gate control signal GCS from the timing controller 21. A shift register 23 and a sampling signal (SAM) for outputting a sampling signal (SAM) in response to a source start pulse (SSP) and a source shift clock (SSC) from the controller 21. Image data (Data) is sequentially sampled according to the SAM, and the source data (SOE; Source Output Enable) and the image data (Data) are supplied from the timing controller 21. A latch section 24 for simultaneously outputting the data to the DAC 25 and an output buffer 27 for amplifying the analog data voltage AData from the DAC 25 and supplying them to the respective data lines DL1 to DLm. Equipped.

The timing controller 21 generates a gate control signal GCS, a source shift clock SSC, a source start pulse SSP, a source output enable signal SOE, and the like, and generates gate and data lines GL1 to GLn and DL1. To DLm).

The shift register 23 generates the sampling signal SAM by using the source shift clock SSC and the source start pulse SSP from the timing controller 21. In detail, the shift register 23 shifts the source start pulse SSP according to the source shift clock SSC to generate a sampling signal SAM, and sequentially supplies the sampling signal SAM to the latch unit 24.

The latch unit 24 sequentially samples the image data Data supplied from the timing controller 21 in accordance with the sampling signal SAM from the shift register 23. The sampled data is stored in units of one line and simultaneously outputs the stored one line of latched image data DData to the DAC 25 in response to the source output enable signal SOE.

The gamma voltage controller 28 is a display position for each horizontal line of digital image data RGB by interpolation using the central color temperature correction coefficient GM and the upper and lower color temperature correction coefficients CM of the curved display panel 1. And generates and outputs correction data Idata to correct the gamma voltage level. Here, the central color temperature correction coefficient GM and the upper / lower color temperature correction coefficient CM are coefficients for converting the average voltage level, the maximum voltage level, or at least one gamma voltage level of the gamma voltage set. Accordingly, the gamma voltage controller 28 corrects the gamma voltage levels, that is, the correction data Idata, so that the gamma voltage level is corrected for each image display position in the horizontal line unit by interpolation using the center and the upper and lower color temperature correction coefficients GM and CM. ) Therefore, the correction coefficients included in the correction data Idata are set in units of horizontal lines, respectively. Technical features of the gamma voltage controller 28 and a method of generating correction data Idata will be described in detail later with reference to the accompanying drawings.

The gamma voltage generator 26 generates a plurality of levels of reference gamma voltages in a divided mode between resistors connected in series between a predetermined maximum and minimum reference gamma voltage when a gamma selection signal VREG is input. The gamma voltage set is generated by subdividing the generated plurality of reference gamma voltages into a plurality of divided modes so as to correspond to grayscale values of the digital image data RGBs. The voltage level of the gamma voltage set is modulated and output in units of at least one horizontal line in accordance with the correction data Idata from the gamma voltage controller 28. At this time, the gamma voltage sets MV0 to MV255 output according to the interpolation correction data Idata are converted into analog data voltages by compensating the correlated color temperature of the digital image data RGB according to the display position of each horizontal line. Are the voltages.

The DAC 24 is a gamma voltage set MV0 to MV255 input from the gamma voltage generator 26 in units of at least one horizontal line, that is, a gamma voltage set inputted so that the voltage level is converted or maintained in units of at least one horizontal line. MV0 to MV255) are used to convert the digital data signal RData into analog image data AData.

The output buffer 27 amplifies the analog image data AData to prevent the data voltage AData from the DAC 25 from being distorted according to the RC time constants of the data lines DL1 to DLm. (VS) is supplied to each of the data lines DL1 to DLm.

FIG. 4 is a graph for describing a method of generating correction data of the gamma voltage controller shown in FIG. 3.

The gamma voltage controller 28 uses the interpolation method shown in Equations 1 and 2 below to determine the gamma voltage level according to the display position of the digital image data RGB for each of the upper and lower ends of the curved display panel 1. Correction data Idata including correction coefficients for causing this correction are generated.

[Equation 1]

Upper part correction data (Idata) = GM-(GM-CM) × each horizontal line / (B × 2)

[Equation 2]

Lower part correction data (Idata) = CM-(GM-CM) × each horizontal line / (B × 2)

Here, GM is the central color temperature correction coefficient and CM is the upper and lower color temperature correction coefficients. And B is the number of total horizontal lines (or horizontal line resolution).

As such, the gamma voltage controller 28 corrects the gamma voltage level to be corrected according to the display position of the digital image data RGB for each of the upper and lower ends of the curved display panel 1 by using the interpolation method shown in Equations 1 and 2. Coefficients, i.e., correction data Idata, are generated and output.

Correction coefficients, ie correction data Idata, which allow the gamma voltage level to be corrected, are coefficients for converting the average voltage level or the maximum voltage level or at least one gamma voltage level of the gamma voltage set.

The correction data Idata generated by the interpolation method according to Equations 1 and 2 is set such that the correction coefficient becomes larger as the upper and lower parts are closer to the upper and lower parts as shown in FIG. Therefore, the color temperature compensation degree of the digital image data displayed at the upper and lower parts may be increased, and the color temperature compensation degree of the digital image data displayed near the center may be smaller.

5A through 5C are other graphs for describing a method of generating correction data of the gamma voltage controller shown in FIG. 3.

The gamma voltage controller 28 receives and stores the central color temperature correction coefficient GM and the upper and lower color temperature correction coefficients CM for each of the red, green, and blue colors of the curved display panel 1, and stores the red, green, and red colors. The gamma voltage level of red, green, and blue is increased depending on the display position of each horizontal line of digital image data (RGB) by interpolation using the central color temperature correction coefficient (GM) and the upper / lower color temperature correction coefficient (CM) for each blue color. Each of the red, green, and blue correction data R_Idata, G_Idata, and B_Idata may be generated and output.

The gamma voltage control unit 28 uses the interpolation method shown in Equations 1 and 2 to display the red, green, and blue image data RGBs at the upper and lower ends of the curved display panel 1. Accordingly, red, green, and blue correction data R_Idata, G_Idata, and B_Idata are generated, respectively, including correction coefficients for correcting the gamma voltage level.

Correction coefficients, i.e., red, green, and blue correction data Idata, which allow the gamma voltage level to be corrected, convert the average gamma voltage level, the maximum gamma voltage level, or at least one gamma voltage level of each of the red, green, and blue colors. Coefficients to make it appear. The red, green, and blue correction data (R_Idata, G_Idata, B_Idata) generated by interpolation according to Equations 1 and 2 are larger as the upper and lower portions are closer to the upper and lower portions, as shown in FIGS. The higher the correction factor is set. Therefore, the color temperature compensation degree of the digital image data displayed at the upper and lower parts may be increased, and the color temperature compensation degree of the digital image data displayed at the center may be smaller.

As described above, the curved flat panel display device and the driving method thereof according to the embodiment of the present invention have the color temperature correction coefficients GM, CM of the center and the upper / lower positions according to the display position of the digital image data RGB. The digital image data RGB can be converted into an analog data voltage so as to compensate for the correlated color temperature by converting the gamma voltage level. In this way, by correcting the correlated color temperature so as not to be distorted according to the viewing angle of the curved flat panel display, the image display quality and its reliability can be improved.

On the other hand, the present invention described above is not limited to the above-described embodiment and the accompanying drawings, it is possible that various substitutions, modifications and changes within the scope without departing from the technical spirit of the present invention It will be apparent to those skilled in the art.

Claims (10)

A curved display panel formed with a plurality of pixel regions;
A power supply unit applying first and second power signals to power lines of the curved display panel;
The central color temperature correction coefficient and the upper and lower color temperature correction coefficients of the curved display panel are respectively stored, and the gamma voltage level is converted by using the central and upper and lower color temperature correction coefficients, thereby displaying digital image data in its display position. And a driving integrated circuit converting the analog color voltage into a corresponding analog data voltage to compensate for the correlated color temperature, and displaying an image by the correlated color temperature compensated data voltage on the curved display panel.
The driving integrated circuit
A timing controller for controlling the driving timing of the gates and data lines of the curved display panel, setting a gamma voltage level, and aligning and outputting the digital image data to be suitable for driving the curved display panel;
Generating and outputting correction data for correcting the gamma voltage level according to the display position of each horizontal line of the digital image data by interpolation using a central color temperature correction coefficient and an upper / lower color temperature correction coefficient of the curved display panel. Gamma voltage controller,
In response to a gamma selection signal from the timing controller, a gamma voltage set is generated by subdividing a reference gamma voltage so as to correspond to grayscale values of the digital image data, and generating the gamma voltage set in at least one horizontal line unit according to the correction data. A gamma voltage generator for modulating and outputting a voltage level of
A digital-to-analog converter configured to convert digital image data of one horizontal line into an analog data voltage by using a gamma voltage set modulated by at least one horizontal line and input the same;
The gamma voltage controller
The correction data including correction coefficients for correcting the gamma voltage level according to the display position of the digital image data for each of the upper and lower portions of the curved display panel using the interpolation method shown in Equations 1 and 2 below. Create,
[Equation 1]
Upper part correction data (Idata) = GM-(GM-CM) × each horizontal line / (B × 2)
[Equation 2]
Lower part correction data (Idata) = CM-(GM-CM) × each horizontal line / (B × 2)
Wherein GM is a central color temperature correction coefficient, CM is an upper / lower color temperature correction coefficient, and B is a number of all horizontal lines (or horizontal line resolution). delete delete The method of claim 1,
The correction data is
Correction coefficients for converting the average voltage level or the maximum voltage level or at least one gamma voltage level of the gamma voltage set,
The closer to the top and bottom of the curved display panel, the larger the correction coefficients, and the closer to the center, the smaller the correction coefficients, the higher the color temperature compensation degree of the digital image data displayed at the upper and lower ends, Curved flat panel display characterized in that the color temperature compensation degree of the digital image data displayed closer to the center is smaller. The method of claim 1,
The gamma voltage controller
The central color temperature correction coefficient and the upper and lower color temperature correction coefficients of the curved display panel are supplied and stored for each of red, green, and blue, respectively,
Red, green, and blue gamma voltage levels are corrected according to the display position of each horizontal line of the digital image data by interpolation using the central color temperature correction coefficients of the red, green, and blue colors and the upper and lower color temperature correction coefficients. And generating and outputting the correction data of green and blue, respectively. Applying first and second power signals to power lines of the curved display panel;
The digital image data is displayed by storing the central color temperature correction coefficient and the upper and lower color temperature correction coefficients of the curved display panel, respectively, and converting the gamma voltage level by using the central and upper and lower color temperature correction coefficients. Converting to an analog data voltage such that a correlation color temperature is compensated for; And
Displaying an image by an analog data voltage with the correlation color temperature compensated on the curved display panel;
Converting the analog data voltage so that the correlated color temperature is compensated
Setting a gamma voltage level and outputting the digital image data in alignment with the driving of the curved display panel;
Generating and outputting correction data for correcting the gamma voltage level according to the display position of each horizontal line of the digital image data by interpolation using a central color temperature correction coefficient and an upper / lower color temperature correction coefficient of the curved display panel. step,
In response to the gamma selection signal, a gamma voltage set is generated by subdividing a reference gamma voltage so as to correspond to grayscale values of the digital image data, and generating a gamma voltage set in units of at least one horizontal line according to the correction data. Modulating and outputting, and
Converting the digital image data of one horizontal line into an analog data voltage using a gamma voltage set modulated by at least one horizontal line unit and outputting the same;
Generating and outputting the correction data
The correction data including correction coefficients for correcting the gamma voltage level according to the display position of the digital image data for each of the upper and lower portions of the curved display panel using the interpolation method shown in Equations 1 and 2 below. Create,
[Equation 1]
Upper part correction data (Idata) = GM-(GM-CM) × each horizontal line / (B × 2)
[Equation 2]
Lower part correction data (Idata) = CM-(GM-CM) × each horizontal line / (B × 2)
Wherein GM is a central color temperature correction coefficient, CM is an upper / lower color temperature correction coefficient, and B is a number of horizontal lines (or horizontal line resolution). . delete delete The method of claim 6,
The correction data is
Correction coefficients for converting the average voltage level or the maximum voltage level or at least one gamma voltage level of the gamma voltage set,
The closer to the top and bottom of the curved display panel, the larger the correction coefficients, and the closer to the center, the smaller the correction coefficients, the higher the color temperature compensation degree of the digital image data displayed at the upper and lower ends, A method of driving a curved flat panel display, characterized in that the color temperature compensation degree of the digital image data displayed near the center is made smaller. The method of claim 6,
Generating and outputting the correction data
The central color temperature correction coefficient and the upper and lower color temperature correction coefficients of the curved display panel are supplied and stored for each of red, green, and blue, respectively,
Red, green, and blue gamma voltage levels are corrected according to the display position of each horizontal line of the digital image data by interpolation using the central color temperature correction coefficients of the red, green, and blue colors and the upper and lower color temperature correction coefficients. And generating and outputting the correction data of green and blue, respectively.

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