KR102664736B1 - A image display device possible of a color reproduction range compensating, and color reproduction range compensating method - Google Patents

Abstract

The present invention presents a video display device and a color gamut compensation processing method that can compensate for color gamut by reflecting the driving voltage reduction deviation of the video display panel.
An image display device including a color gamut compensation processing unit according to an embodiment of the present invention analyzes the hue, saturation, and luminance characteristics of image data, and the degree of saturation change for each hue according to the change in luminance characteristics. By detecting and compensating for saturation change characteristics, it is possible to prevent image quality degradation due to driving voltage reduction deviation. In addition, the present invention can further improve color reproduction rate and increase user satisfaction by additionally correcting the saturation correction gain value for each hue according to the luminance characteristics and saturation characteristics of the input image data and applying it to the saturation correction parameter.

Description

Video display device capable of color gamut compensation and color gamut compensation processing method {A IMAGE DISPLAY DEVICE POSSIBLE OF A COLOR REPRODUCTION RANGE COMPENSATING, AND COLOR REPRODUCTION RANGE COMPENSATING METHOD}

The present invention relates to an image display device that can compensate for color gamut by reflecting the driving voltage reduction deviation of an image display panel and a color gamut compensation processing method.

In the recent information age, flat-type video display devices are becoming popular at a rapid pace. Due to the characteristics of these flat-type video display devices, such as light weight, thinness, and low power consumption, their application range is gradually expanding to include not only TVs, monitors, and laptops, but also mobile phones, PDAs, and smartphones.

In particular, organic light emitting diode displays (Organic Light Emitting Displays), which have high brightness, low driving voltage, and can be made ultra-thin, are mainly used in mobile communication devices such as smartphones and tablet pads.

Because organic light emitting diode displays have the advantages of a wide viewing angle, excellent contrast, and fast response speed, they are more useful in mobile communication devices than liquid crystal displays, which require an additional backlight unit.

In general, an organic light emitting diode display device includes an image display panel in which pixel areas displaying red, green, and blue colors are arranged in a matrix, and an organic light emitting diode configured in each pixel area and pixel circuits of the organic light emitting diode are controlled. It is composed of driving integrated circuits that

Conventionally, when a video display panel is manufactured, the color coordinate characteristics of red, green, and blue are determined according to the light emission characteristics of the color filter or organic light emitting diode placed in each pixel area of the video display panel, and the color gamut is determined through a color coordinate mapping algorithm. set. In this way, by adjusting the color reproduction rate through a preset color coordinate mapping algorithm according to the characteristics of the video display panel, the color reproduction characteristics of each video display panel could be varied or the video display characteristics could be varied according to the user's preferred color.

A problem of image quality deterioration that has recently emerged is that the luminance and saturation characteristics of the displayed image are variable due to the deviation of driving voltage reduction due to the wiring resistance of the video display panel, such as IR drop.

In particular, when the wiring resistance of the video display panel increases, the luminance decreases due to the driving voltage reduction deviation and conversely, the saturation increases, resulting in a color difference in each video display area large enough to be perceived by the eye.

Accordingly, in order to solve the problems and meet the requirements of the prior art, the present invention presents an image display device and a color gamut compensation processing method that can compensate for the color gamut by reflecting the driving voltage reduction deviation of the image display panel. .

Specifically, the problem to be solved according to an embodiment of the present invention is to analyze the hue, saturation, and luminance (or value) characteristics of image data, and change the saturation for each hue according to the change in luminance characteristics. The goal is to provide an image display device that can detect the degree and compensate for saturation change characteristics and a color gamut compensation processing method.

In addition, the present invention provides a video display device that can calculate saturation correction gain values for each hue according to changes in luminance characteristics, further correct the calculated saturation correction gain values according to luminance characteristics and saturation characteristics, and apply them to saturation correction parameters. It provides a color gamut compensation processing method.

Problems to be solved according to embodiments of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the description below.

The color gamut compensation processing unit of the video display device according to an embodiment of the present invention analyzes the hue, saturation, and luminance characteristics of image data input from the outside, detects the degree of saturation change for each hue according to the change in luminance characteristics, and determines the saturation change characteristics. By compensating, corrected image data with compensated saturation characteristics is generated and output.

To this end, the color gamut compensation processing unit according to the present invention uses a saturation correction parameter generator to generate color coordinate modulation parameters for modulating the saturation characteristics of image data, and uses a saturation correction gain generator to classify color tones according to changes in luminance of the video display panel. Saturation correction gain values are extracted from memory. Then, a saturation compensation parameter is generated by calculating and processing the color coordinate modulation parameters for modulating the saturation characteristic and the extracted saturation correction gain value, and then the saturation data is modulated so that the saturation characteristic is compensated using the saturation compensation parameter.

Accordingly, the image data conversion unit configured in the color gamut compensation processing unit may convert the saturation data modulated by the saturation compensation parameter, the hue data of the image data, and the luminance data into red, green, and blue corrected image data and output them.

In addition, the color gamut compensation processing method according to an embodiment of the present invention generates color coordinate modulation parameters for modulating the saturation characteristics of image data, and extracts saturation correction gain values for each hue according to changes in luminance of the image display panel from memory. It includes steps to:

In addition, the method further includes generating a saturation compensation parameter by calculating and processing the color coordinate modulation parameters for modulating the saturation characteristic and the extracted saturation correction gain value, and then modulating the saturation data so that the saturation characteristic is compensated using the saturation compensation parameter. . Accordingly, the saturation data modulated by the saturation compensation parameter, the hue data of the image data, and the luminance data can be converted into red, green, and blue corrected image data and output.

The video display device capable of color gamut compensation and the color gamut compensation processing method according to an embodiment of the present invention compensate for the color gamut by reflecting the driving voltage reduction deviation of the video display panel, thereby preventing image quality degradation due to the driving voltage reduction deviation. There is a possible effect.

In particular, the video display device including the color gamut compensation processing unit of the present invention stores in advance the saturation change difference value (i.e., saturation correction gain value) for each hue according to the change in luminance characteristics analyzed for each video display panel, and performs saturation correction for each hue. The saturation change characteristic can be compensated for using the gain value. Accordingly, the saturation change characteristic can be compensated for using a simple circuit configuration with additional memory and a simple processor.

In addition, by additionally correcting the saturation correction gain value for each hue according to the luminance characteristics and saturation characteristics of the input image data and applying it to the saturation correction parameter, the color reproduction rate can be further improved, thereby increasing user satisfaction.

The effects according to the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description below.

Figure 1 is a detailed configuration diagram of an image display device including a color gamut compensation processing unit according to an embodiment of the present invention.
FIG. 2 is a block diagram specifically illustrating the color gamut compensation processing unit shown in FIG. 1.
FIG. 3 is a color coordinate diagram for explaining a method of generating hue, luminance, and saturation correction parameters of the color gamut compensation processing unit shown in FIG. 2.
FIG. 4 is a diagram for explaining a method of detecting saturation correction gain values for each hue of the saturation correction gain generator shown in FIG. 2.
FIG. 5 is a graph for explaining a method of correcting the saturation correction gain value of the luminance-based gain correction unit shown in FIG. 2.
FIG. 6 is a graph for explaining a method of additionally correcting the saturation correction gain value of the saturation-based gain correction unit shown in FIG. 2.

The above-described objects, features, and advantages will be described in detail later with reference to the attached drawings, so that those skilled in the art will be able to easily implement the technical idea of the present invention. In describing the present invention, if it is determined that a detailed description of known technologies related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted.

Hereinafter, an image display device including a color gamut compensation processing unit and a color gamut compensation processing method according to an embodiment of the present invention will be described in detail with reference to the attached drawings.

Image display devices including the color gamut compensation processing unit of the present invention include a liquid crystal display, a field emission display, an organic light emitting diode display, and a quantum dot display. (Quantum Dot Display) etc. may be applied.

Hereinafter, an organic light emitting diode display device applied to a mobile communication device will be described as an example.

Figure 1 is a detailed configuration diagram of an image display device including a color gamut compensation processing unit according to an embodiment of the present invention.

The organic light emitting diode display device shown in FIG. 1 includes an image display panel 100, a driving circuit unit 200, a power supply unit 300, and a color gamut compensation processing unit 400.

Although FIG. 1 shows an example in which the color gamut compensation processing unit 400 is configured separately from the driving circuit unit 200, etc., the color gamut compensation processing unit 400 may be included in the driving circuit unit 200 and be integrated with the driving circuit unit 200. You can. In addition, although not shown in the drawing, when the color gamut compensation processing unit 400 is applied to a large screen video display device, it includes at least one driving circuit such as a timing control circuit, a gate driving circuit, and a data driving circuit, and one chip (1 chip). ) may be integrated and configured as a type.

The image display panel 100 displays an image by forming sub-pixels (P) in each pixel area arranged in a matrix form. Each sub-pixel P includes an organic light-emitting diode and a diode driving circuit that independently drives the organic light-emitting diode. The form in which each sub-pixel P is arranged in each pixel area is not limited to a matrix form, and may be arranged in various ways depending on the usage characteristics, such as a stripe form or a form in which pixels are shared.

The diode driving circuit of each sub-pixel (P) supplies respective gate lines (GL), data lines (DL), and power to the pixel area defined by each gate line (GL1 to GLn) and data lines (DL1 to DLm). It is configured to be connected to the line (PL). Additionally, organic light emitting diodes (not shown) are configured between the diode driving circuit and the first and second power signals (VDD and GND).

The diode driving circuits of each sub-pixel (P) supply analog image signals from each connected data line (DL) to the light emitting diode and charge the analog image signal to maintain the light-emitting state.

The driving circuit unit 200 of an organic light emitting diode display applied to a mobile communication device is configured to display the red, green, and blue corrected image data (R'G'B') input from the color gamut compensation processing unit 400 as an image. The gate and data lines (GL1 to GLn and DL1 to DLm) of the display panel 100 are driven.

Specifically, the driving circuit unit 200 displays the corrected image data (R'G'B') input from the color gamut compensation processing unit 400 using at least one synchronization signal (DCLK, Hsync, Vsync, DE). Align appropriately to the driving characteristics of the panel 100, such as resolution and driving frequency. Then, the corrected video data (R'G'B') is converted to an analog video signal, that is, a video voltage, and the video signal (for example, analog video voltage) for one horizontal line is transmitted to each data line (for example, analog video voltage) for each horizontal cycle. DL1 to DLm).

Additionally, the driving circuit unit 200 generates gate control signals for driving the plurality of gate lines GL1 to GLn using at least one synchronization signal DCLK, Hsync, Vsync, and DE. And, using the gate control signal, scan pulses are sequentially supplied to each gate line (GL1 to GLn) every horizontal cycle. Here, a gate-off voltage is supplied during a period when scan pulses are not supplied to the gate lines GL1 to GLn. Accordingly, the driving circuit unit 200 causes the diode driving circuits connected to the gate lines GL1 to GLn to be sequentially driven in units of the gate line GL every one horizontal period.

The color gamut compensation processing unit 400 reflects the saturation characteristics of image data (RGB) input from the outside to compensate for the color gamut by reflecting the driving voltage reduction deviation due to the wiring resistance of the video display panel 100, such as IR drop. Correct. That is, the color gamut compensation processing unit 400 corrects the image data (RGB) so that the saturation characteristic is modulated by reflecting the luminance lowering characteristic and the resulting saturation increasing characteristic due to the driving voltage reduction deviation of the image display panel 100.

As described above, when the luminance of the display image decreases due to the driving voltage reduction deviation, the saturation of the display image increases accordingly, and thus the image quality may be distorted. Accordingly, the color gamut compensation processing unit 400 according to the present invention sets and stores the degree of change in hue characteristics and saturation characteristics according to changes in luminance characteristics (eg, size of luminance data) of the displayed image as a saturation correction gain value. In addition, by correcting the saturation characteristics (size of saturation data) of the image data using the saturation correction gain value for each hue according to the change in display brightness, the saturation characteristic can be displayed without increasing or distorting even if the brightness of the displayed image decreases. .

To explain this in more detail, the color gamut compensation processing unit 400 compensates for the degree of saturation change for each hue according to the change in display luminance of each video display panel 100, which is analyzed in advance for each video display panel 100, that is, saturation compensation for each hue. Save the gain value in advance. In addition, the color gamut compensation processing unit 400 uses the degree of saturation change for each hue according to the display luminance change of the image display panel 100 as a saturation correction gain value to correct the saturation change characteristic for the input image data (RGB). , Generate and output corrected image data (R'G'B').

To this end, the color gamut compensation processing unit 400 extracts hue, luminance, and saturation data of image data (RGB) for each unit pixel that is sequentially input, and drives the size and resolution of the corresponding image display panel 100. Color coordinate modulation parameters are created to modulate hue, luminance, and saturation data according to characteristics.

In addition, the color gamut compensation processing unit 400 sequentially reads the saturation correction gain values for each hue of image data (RGB) for each unit pixel, and converts the read saturation correction gain values for each chromaticity into color coordinates generated for saturation data modulation. By processing modulation parameters and operations, the color coordinate modulation parameters for saturation data modulation are varied.

In addition, the color gamut compensation processing unit 400 includes a color coordinate modulation parameter for modulating hue data of image data (RGB) for each unit pixel, a color coordinate modulation parameter for modulating luminance data, and a color coordinate modulation parameter varied for modulating the saturation data. Each is used to modulate the hue, luminance, and saturation data. Then, the modulated hue, luminance, and saturation data are converted into red, green, and blue image data to generate corrected image data (R'G'B') in which the saturation change characteristics are compensated. The corrected image data R'G'B' generated here is sequentially supplied to the driving circuit unit 200.

Meanwhile, the color gamut compensation processing unit 400 converts the saturation correction gain value for each hue of image data (RGB) for each unit pixel into a first correction gain value preset to correspond to luminance data and a second correction gain value preset to correspond to saturation data. Additional correction can be made sequentially depending on the gain value. In this case, the color coordinate modulation parameter for saturation data modulation can be varied by processing the additionally corrected saturation correction gain value with the color coordinate modulation parameter generated for saturation data modulation. This color gamut compensation processing unit 400 will be described in more detail later with reference to the attached drawings.

FIG. 2 is a block diagram specifically illustrating the color gamut compensation processing unit shown in FIG. 1.

The color gamut compensation processing unit 400 shown in FIG. 2 includes an HSV data conversion unit 410, a hue correction parameter generator 411, a luminance correction parameter generator 412, a saturation correction parameter generator 413, and a saturation correction unit. It includes a gain generator 420, a memory 450, a luminance-based gain correction unit 430, a saturation-based gain correction unit 440, and a correction calculation unit 460. In addition, the color gamut compensation processing unit 400 further includes a hue correction unit 414, a luminance correction unit 415, a saturation correction unit 416, and an image data conversion unit 470.

The HSV data conversion unit 410 converts the image data (RGB) for each unit pixel input from the outside into hue data, luminance data, and saturation data by calculating them using a preset equation or substituting them in a lookup table. Hue data, luminance data, and saturation data are transmitted to the hue correction parameter generator 411, the luminance correction parameter generator 412, and the saturation correction parameter generator 413, respectively. In addition, hue data and saturation data can be simultaneously transmitted to the saturation correction gain generator 420 and memory 450.

FIG. 3 is a color coordinate diagram for explaining a method of generating hue, luminance, and saturation correction parameters of the color gamut compensation processing unit shown in FIG. 2.

Referring to FIG. 3, the color correction parameter generator 411 creates a color coordinate modulation parameter (HS) for modulating the color tone data of the image data (RGB) to suit the driving characteristics such as the size and resolution of the image display panel 100. Create. Specifically, the color correction parameter generator 411 reads driving characteristic information such as size, resolution, and driving frequency for the corresponding video display panel 100 from external memory or internal memory 450. Then, a color coordinate modulation parameter (HS) is generated to modulate the color tone data of the red, green, and blue image data (R1, G1, and B1) according to the driving characteristics of the image display panel 100.

Likewise, the luminance correction parameter generator 412 reads driving characteristic information, such as size, resolution, and driving frequency, for the video display panel 100 from the external memory or internal memory 450. Then, a color coordinate modulation parameter (VS) is generated to modulate the luminance data of the red, green, and blue image data (R1, G1, and B1) according to the read driving characteristic information.

In addition, the saturation correction parameter generator 413 generates a color coordinate modulation parameter (G) for modulating the saturation data of the red, green, and blue image data (R1, G1, and B1) according to the driving characteristics of the image display panel 100. Create.

The color coordinate modulation parameter (HS) generated by the hue correction parameter generator 411, the color coordinate modulation parameter (VS) generated by the luminance correction parameter generator 412, and the color coordinate modulation generated by the saturation correction parameter generator 413. If the parameter (G) is applied to the input image data (R1, G1, B1), the coordinates can be corrected into red, green, and blue image data (R2, G2, B2), as shown in FIG. 3.

FIG. 4 is a diagram for explaining a method of detecting saturation correction gain values for each hue of the saturation correction gain generator shown in FIG. 2.

Referring to FIG. 4(a), when the saturation data and saturation data (S) of the image data (RGB) for each unit pixel are received, the saturation correction gain generator 420 generates the image data (RGB) for each unit pixel. Saturation correction gain values (GS) corresponding to saturation data (S) for each hue are sequentially read from the memory 450.

Specifically, referring to FIG. 4(b), the memory 450 contains a color tone (1: Blue ~ 3: Magenta ~ 5: Red ~) according to the change in display luminance (LUTmin, LUTmid, LUTmax) of the image display panel 100. The saturation change difference value (saturation change interval) for each 9:Green ~ 12) is stored in advance as the saturation correction gain value (GS) for each hue.

The saturation correction gain value (GS) for each color tone (1: Blue ~ 3: Magenta ~ 5: Red ~ 9: Green ~ 12) according to the display luminance change (LUTmin, LUTmid, LUTmax) of the video display panel 100 is It is calculated in advance as an experimental value for each video display panel 100. Here, the saturation correction gain value (GS) for each hue (1:Blue ~ 3:Magenta ~ 5:Red ~ 9:Green ~ 12) is the saturation change when the luminance is changed to the minimum or maximum luminance based on the intermediate luminance (LUTmid). It can be set as a difference value (saturation change interval). For example, the saturation change difference value (saturation change interval) when changing from the intermediate luminance (LUTmid) to the minimum luminance (LUTmin) is the smallest saturation change difference at the minimum luminance compared to the intermediate luminance when the hue data is 7, When the hue data is 3 (Magenta), the difference in saturation conversion appears the largest at the minimum luminance compared to the medium luminance.

Accordingly, when the saturation correction gain generator 420 receives the saturation data (S) of the image data (RGB) for each unit pixel, the saturation correction gain value (GS) corresponding to the saturation data (S) for each hue is stored in a memory ( It can be sequentially read from 450 and transmitted to the luminance-based gain correction unit 430 or correction calculation unit 460.

When the saturation correction gain generation unit 420 directly transmits the saturation correction gain value (GS) to the correction calculation unit 460, the correction calculation unit 460 generates a color coordinate modulation parameter ( A saturation compensation parameter (GSS) is generated by performing a multiplication operation on G) and the saturation compensation gain value (GS).

Accordingly, the image data converter 470 converts the hue data, luminance data, and saturation data modulated by the saturation compensation parameter (GSS) of the image data (RGB) into red, green, and blue corrected image data (R'G'). B') can be converted to B' and sequentially supplied to the driving circuit unit 200.

On the other hand, when the saturation correction gain generator 420 transmits the saturation correction gain value (GS) to the luminance-based gain correction unit 430, the luminance-based gain correction unit 430 transmits the received saturation correction gain value (GS) is first corrected based on the luminance data of the image data (RGB) for each unit pixel. This will be described in more detail with reference to FIG. 5 as follows.

FIG. 5 is a graph for explaining a method of correcting the saturation correction gain value of the luminance-based gain correction unit shown in FIG. 2.

Referring to FIG. 5, the luminance-based gain correction unit 430 is a luminance-based gain correction unit 430 that is preset according to the luminance value (V) inclusion range (LUTmin, LUTmid, LUTmax) of the luminance data converted and extracted by the HSV data conversion unit 410. Correction gain values (VG) are sequentially read from the memory 450. Then, the saturation correction gain value (GS) is first corrected by multiplying the saturation correction gain value (GS) input from the saturation correction gain generator 420 by the luminance-based correction gain value (VG).

The luminance-based correction gain value (VG) can be preset to gradually lower to less than 1 according to the increasing luminance value (V) of the luminance data when the luminance value (V) of the luminance data increases above the mid-luminance range (LUTmin). there is.

Specifically, when the luminance value (V) inclusion range (LUTmin, LUTmid) of the luminance data is included in the lowest luminance range, including the middle luminance range, the luminance-based correction gain value (VG) is set so that the saturation correction gain value (GS) remains the same. ) can be set to 1.

On the other hand, if the range containing the luminance value (V) of the luminance data increases beyond the intermediate luminance range (LUTmin) to the maximum luminance range (LUTmax), there are limits to luminance implementation, so the saturation correction gain value (GS) is lowered based on the luminance. The correction gain value (VG) may be preset to be lowered to less than 1. In this way, the saturation correction gain value (GV) that is first corrected by multiplying the luminance-based correction gain value (VG) is transmitted to the saturation-based gain correction unit 440.

The saturation-based gain correction unit 440 secondarily corrects the firstly corrected saturation correction gain value (GV) based on the saturation data of the image data (RGB) for each unit pixel, and creates the secondly corrected saturation correction gain value ( GS') is transmitted to the correction calculation unit 460. This will be described in more detail with reference to FIG. 6 as follows.

FIG. 6 is a graph for explaining a method of additionally correcting the saturation correction gain value of the saturation-based gain correction unit shown in FIG. 2.

Referring to FIG. 6, the saturation-based gain correction unit 440 is a preset saturation-based gain correction unit 440 according to the saturation value (S) included range (0% to 100%) of the saturation data converted and extracted by the HSV data conversion unit 410. The correction gain value (SG) is sequentially read from the memory 450. Then, by multiplying the saturation correction gain value (GV) first corrected from the luminance-based gain correction unit 430 by the saturation-based correction gain value (SG) read from the memory 450, the first corrected saturation correction gain is obtained. Perform secondary correction of the value (GV). The secondary corrected saturation correction gain value (GS') is transmitted to the correction calculation unit 460. Here, the saturation-based correction gain value (SG) may be preset to be lowered by a preset value in inverse proportion to the saturation value (S) of the saturation data.

The correction operation unit 460 calculates the color coordinate modulation parameter (G) generated for modulating the saturation data of the image data (RGB) and the saturation correction gain value (GS') secondaryly corrected by the saturation-based gain correction unit 440 in real time. A saturation compensation parameter (GSS) is generated by processing the multiplication operation. The saturation compensation parameter (GSS) generated in real time is supplied to the saturation correction unit 416.

The hue correction unit 414 calculates or multiplies the color coordinate modulation parameters (HS) and hue data (H) for hue correction generated in the hue correction parameter generator 411 according to a preset equation to generate the corresponding hue data (H). ) is modulated.

The luminance correction unit 415 calculates or multiplies the color coordinate modulation parameter (VS) and luminance data (V) for luminance correction generated by the luminance correction parameter generator 412 according to a preset equation to obtain the corresponding luminance data (V ) is modulated.

The saturation correction unit 416 modulates the saturation compensation parameter (GSS) and the saturation data (S) generated by the saturation correction calculation unit 460 by calculating or multiplying the saturation compensation parameter (GSS) and the saturation data (S) according to a preset equation.

The image data conversion unit 470 converts the hue data modulated by the hue correction unit 414, the luminance data modulated by the luminance correction unit 415, and the saturation data modulated by the saturation correction unit 416 into a preset calculation formula. By converting the image data into red, green, and blue by calculating or substituting it into a lookup table, corrected image data (R'G'B') with the saturation change characteristics compensated is generated. Then, the corrected image data R'G'B' is sequentially transmitted to the driving circuit unit 200.

Accordingly, the driving circuit unit 200 aligns the corrected image data (R'G'B') input from the color gamut compensation processing unit 400 to suit the driving characteristics such as resolution and driving frequency of the video display panel 100, The aligned corrected image data (R'G'B') can be converted into an analog video signal and supplied to each data line (DL1 to DLm).

In this way, the image display device and the color gamut compensation method using the color gamut compensation processor 400 according to an embodiment of the present invention reflect the driving voltage reduction deviation of the image display panel 100 and compensate for the color gamut for saturation characteristics, etc. , it is possible to prevent image quality degradation due to driving voltage reduction deviation.

In particular, the color gamut compensation processing unit 400 of the present invention stores in advance saturation change data for each hue according to the luminance change analyzed for each driving characteristic of the video display panel 100, that is, saturation correction gain value (GS) for each hue, Saturation change characteristics can be compensated for by using the saturation correction gain value (GS) for each hue. Accordingly, the saturation change characteristic can be compensated for using a simple circuit configuration in which the memory 450 is added and a simple processor.

In addition, by additionally correcting the saturation correction gain value (GS) for each hue according to the luminance characteristics and saturation characteristics of the input image data (RGB) and applying it to the saturation correction parameter (GSS), the color reproduction rate can be further improved and user satisfaction can be increased. There will be.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and it is commonly known in the technical field to which the present invention pertains that various substitutions, modifications, and changes can be made without departing from the technical details of the present invention. It will be clear to those who have the knowledge of. Therefore, the scope of the present invention is indicated by the claims described later, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention.

100: Video display panel
200: Driving circuit part
300: Power supply unit
410: HSV data conversion unit
420: Saturation correction gain generator
430: Luminance-based gain correction unit
440: Saturation-based gain correction unit
450: memory
460: Correction calculation unit
470: Video data conversion unit

Claims (15)

An image display panel that displays an image by placing a plurality of sub-pixels in intersection areas of the gate and data lines;
a color gamut compensation processor that generates corrected image data with corrected saturation change characteristics by using a saturation change difference value for each hue according to a change in display brightness of the video display panel as a saturation correction gain value; and
A driving circuit unit that drives the gate and data lines so that a corrected image according to the corrected image data is displayed on the image display panel,
The color gamut compensation processing unit
a saturation correction parameter generator that generates color coordinate modulation parameters for modulating the saturation characteristics of image data;
a saturation correction gain generator that extracts saturation correction gain values for each hue according to changes in luminance of the video display panel from the memory;
a correction calculation unit that generates a saturation compensation parameter by processing the color coordinate modulation parameters for modulating the saturation characteristics and the extracted saturation compensation gain value; and
An image data conversion unit that converts the saturation data modulated by the saturation compensation parameter, the hue data of the image data, and the luminance data into red, green, and blue corrected image data, and outputs it.
Video display device.
delete According to claim 1,
an HSV data converter that converts the image data for each unit pixel into the hue data, the luminance data, and the saturation data;
a color correction parameter generator that generates color coordinate modulation parameters for modulating the color tone data to suit the driving characteristics of the video display panel;
a luminance correction parameter generator that generates color coordinate modulation parameters for modulating the luminance data; and
Further comprising a saturation correction parameter generator that generates a color coordinate modulation parameter for modulating the saturation data and transmits it to the correction calculation unit,
Video display device.
According to claim 3,
a luminance-based gain correction unit that first corrects the saturation correction gain value extracted from the saturation correction gain generator based on luminance data of the image data for each unit pixel; and
Further comprising a saturation-based gain correction unit that secondarily corrects the saturation correction gain value first corrected by the luminance-based gain correction unit based on the saturation data,
Video display device.
According to claim 4,
The memory is
Store previously analyzed saturation correction gain values for each hue according to changes in display luminance of the video display panel and share them with the saturation correction gain generator;
Pre-storing luminance-based correction gain values preset according to the luminance value inclusion range of the luminance data and sharing them with the luminance-based gain correction unit,
Each of the saturation-based correction gain values preset according to the saturation value inclusion range of the saturation data is stored and shared with the saturation-based gain correction unit,
Video display device.
According to claim 4,
The correction calculation unit
The color coordinate modulation parameter generated for saturation data modulation of the image data and the saturation correction gain value secondaryly corrected by the saturation-based gain correction unit are processed using a preset calculation formula or a multiplication operation is performed to generate the saturation compensation parameter. ,
Video display device.
According to claim 6,
a color tone correction unit that modulates the color tone data according to the color coordinate modulation parameters generated by the color tone correction parameter generator;
a luminance correction unit that modulates the luminance data according to the color coordinate modulation parameters generated by the luminance correction parameter generation unit; and
Further comprising a saturation correction unit that modulates the saturation data according to the saturation compensation parameter generated by processing in the correction operation unit,
Video display device.
According to claim 7,
The video data conversion unit
The hue data modulated in the hue correction unit, the luminance data modulated in the luminance correction unit, and the saturation data modulated in the saturation correction unit are calculated using a preset equation or substituted into a lookup table to produce red, green, and blue images. Generating the corrected image data in which saturation change characteristics are compensated by converting to data,
Video display device.
In a compensation processing method that compensates for color gamut by modulating the saturation characteristics of image data,
Generating color coordinate modulation parameters for modulating saturation characteristics of image data;
Extracting saturation correction gain values for each hue according to changes in luminance of the video display panel from memory;
generating a saturation compensation parameter by calculating and processing the color coordinate modulation parameters for modulating the saturation characteristics and the extracted saturation correction gain value; and
Containing converting the saturation data modulated by the saturation compensation parameter, the hue data of the image data, and the luminance data into red, green, and blue corrected image data and outputting it.
How to handle color gamut compensation.
According to clause 9,
Converting the image data for each unit pixel into the hue data, the luminance data, and the saturation data, respectively;
generating color coordinate modulation parameters for modulating the color tone data to suit the driving characteristics of the video display panel;
generating color coordinate modulation parameters for modulating the luminance data; and
Further comprising generating a color coordinate modulation parameter for modulating the saturation data,
How to handle color gamut compensation.
According to claim 10,
The step of generating color coordinate modulation parameters for modulating the saturation data is
sequentially extracting a preset luminance-based correction gain value from a memory according to a luminance value inclusion range of the luminance data; and
Comprising the step of first correcting the saturation correction gain value by multiplying the extracted luminance-based correction gain value by the saturation correction gain value,
How to handle color gamut compensation.
According to claim 11,
The step of generating color coordinate modulation parameters for modulating the saturation data is
sequentially extracting a preset saturation-based correction gain value from the memory according to a saturation value inclusion range of the saturation data; and
Further comprising secondly correcting the first corrected saturation correction gain value by multiplying the first corrected saturation correction gain value by the extracted saturation-based correction gain value,
How to handle color gamut compensation.
According to claim 12,
The step of generating the saturation compensation parameter is
Generating the saturation compensation parameter by calculating the color coordinate modulation parameter generated for saturation data modulation of the image data and the secondary corrected saturation correction gain value using a preset equation or performing a multiplication operation,
How to handle color gamut compensation.
According to claim 13,
The step of converting and outputting the red, green, and blue corrected image data is
Modulating hue data according to color coordinate modulation parameters generated for hue modulation;
Modulating luminance data according to color coordinate modulation parameters generated for luminance modulation;
Further comprising modulating the saturation data according to the saturation compensation parameter,
How to handle color gamut compensation.
According to claim 14,
The step of converting and outputting the red, green, and blue corrected image data is
The corrected image in which saturation change characteristics are compensated by converting the modulated hue data, the modulated luminance data, and the modulated saturation data into red, green, and blue image data by calculating them using a preset equation or substituting them in a lookup table. Further comprising the step of generating data,
How to handle color gamut compensation.

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