KR20070075816A - Gamma Control and Gamma Control - Google Patents

Abstract

Disclosed are a gamma adjusting device and a gamma adjusting method capable of shortening a time required for gamma correction. After providing the test signal to the display unit, the luminance of the display unit is measured in some regions of the change region of the test signal. A target voltage versus luminance curve is generated through interpolation using the measured luminance signal and the test signal. A target gamma reference voltage based on the generated target voltage versus luminance curve is generated and stored in the storage unit. After the gamma voltage is generated using the stored gamma reference voltage, the gamma voltage is provided to the display unit. Therefore, the gamma correction time can be shortened as the gamma reference voltage is generated by the V-T curve.

Description

GAMMA CORRECTION DEVICE AND METHOD FOR GAMMA CORRECTING THEROF}

1 is a block diagram schematically illustrating a gamma adjusting device of a liquid crystal display according to an exemplary embodiment of the present invention.

2 shows a voltage versus transmittance curve.

3 is a flowchart for performing a gamma adjusting method by the gamma adjusting apparatus shown in FIG. 1.

Figure 4 is a block diagram showing a gamma adjusting device according to another embodiment of the present invention.

FIG. 5 is a graph illustrating gamma voltage versus luminance characteristics adjusted by the gamma adjusting device shown in FIG. 4.

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

100: test signal providing unit 200: luminance measurement unit

300: control unit 400: storage unit

500: gamma voltage generator 600: liquid crystal display module

The present invention relates to a gamma control device and a gamma control method, and more particularly, to a gamma control device and a gamma control method that can shorten the time required for gamma correction.

In general, in a liquid crystal display, a gray level of an image does not change linearly according to a voltage level of an image signal, and a non-linear gamma characteristic appears. This is due to the fact that the light transmittance of the liquid crystal does not change linearly with the voltage level of the image signal, and the gray scale of the image does not change linearly with the light transmittance of the liquid crystal.

Therefore, the liquid crystal display device is constructing a system that automatically adjusts the gamma characteristics in the production of the product not to exceed the acceptable standard. That is, after the test signal is provided to the liquid crystal display, the system prepares a contrast ratio and gray curve for the luminance for each gray scale by measuring the luminance by the test signal, and then sets the gamma reference voltage. After calculating the resistance value corresponding to each voltage value with respect to the set gamma reference voltage, the gamma reference voltage is reset by manually adjusting the resistance value and the common voltage.

As such, the process of setting an existing gamma reference voltage is very complicated, and thus, a lot of time is required for gamma adjustment.

In addition, in a liquid crystal display device in which one pixel area is divided into a main pixel area and a sub pixel area to improve visibility, different gamma reference voltages exist in the main pixel area and the sub pixel area. This further increases the time required for adjusting the gamma characteristic.

Accordingly, an object of the present invention is to provide a gamma adjusting device for shortening the time for adjusting the gamma characteristics.

Another object of the present invention to provide a gamma control method by the gamma control device described above.

The gamma adjusting device according to the present invention includes a test signal providing unit, a luminance measuring unit, a controller, a storage unit, and a gamma voltage generator. The test signal providing unit provides a test signal to the display unit. The luminance measuring unit measures the luminance of the display unit in a partial region of the change area of the test signal. The controller generates a target voltage band luminance curve through interpolation using the measured luminance signal and the test signal, and generates a gamma reference voltage based on the generated target voltage band transmittance curve. The storage unit stores the gamma reference voltage. The gamma voltage generator generates a gamma voltage in response to the stored gamma reference voltage and provides the gamma voltage to the display unit.

According to the gamma adjusting method of the present invention, the test signal is provided to the display unit, and the luminance of the display unit is measured in some regions of the change region of the test signal. A target voltage versus luminance curve is generated through interpolation using the measured luminance signal and the test signal. A target gamma reference voltage based on the generated target voltage versus luminance curve is generated, and the target gamma reference voltage is stored. A gamma voltage is generated in response to the target gamma reference voltage and provided to the display unit.

According to such a gamma adjusting device and a control method, the VT curve is generated by interpolating luminance after measuring luminance only in a part of a voltage change region, and the gamma correction voltage is generated by the VT curve, thereby reducing the time for gamma correction. You can.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram schematically illustrating a gamma adjusting device of a liquid crystal display according to an exemplary embodiment of the present invention, and FIG. 2 is a diagram illustrating a voltage versus transmittance curve.

As shown in FIG. 1, the gamma adjusting device of the liquid crystal display according to the exemplary embodiment of the present invention includes a test signal providing unit 100, a luminance measuring unit 200, a control unit 300, a storage unit 400, and The gamma voltage generator 500 is included.

The test signal providing unit 100 provides a test signal TS for adjusting the gamma of the liquid crystal display module 600. The test signal TS is a voltage signal for generating a gamma voltage corresponding to the image displayed on the liquid crystal display module 600.

In addition, when the test signal providing unit 100 intends to display an 8-bit data image on the liquid crystal display module 600, the test signal providing unit 100 may output voltage signals having different voltage levels according to 256 (2 ⁸ ) data changes. 600).

The liquid crystal display module 600 includes a display panel 610, a data driver 620, and a gate driver 630 that provide driving control signals for displaying an image on the display panel 610.

The display panel 610 includes a plurality of gate lines GL1 to GLm and a plurality of data lines DL1 to DLn formed to cross the plurality of gate lines GL1 to GLm. The gate driver 620 sequentially supplies gate driving signals to the plurality of gate lines GL1 to GLm. The data driver 630 supplies an image signal corresponding to the test signal TS to the plurality of data lines DL1 to DLn in synchronization with a gate signal. As a result, an image is displayed on the display panel 610.

The luminance measuring unit 200 measures the luminance of the liquid crystal display module 600. That is, the luminance measuring unit 200 measures the luminance of the image displayed on the display panel 610 according to the test signal TS. In this case, the luminance measuring unit 200 measures only some of the change areas of the change area of the test signal TS. For example, when an image generated by an 8-bit test signal TS is displayed on the display panel 610, luminance is measured only in about 24 to 27 areas out of 256 areas that are change areas of the test signal TS. do.

In addition, the luminance measuring unit 200 measures luminance at relatively many measurement points in the region A having a large slope in the voltage versus transmittance (hereinafter, V-T) curve of FIG. Subsequently, the luminance measuring unit 200 provides the measured luminance signal to the controller 300.

The control unit 300 generates a gamma reference voltage using the luminance signal and the test signal TS provided from the luminance measuring unit 200. In more detail, the controller 300 generates the VT curve as shown in FIG. 2 using the measured luminance signal and the test signal TS, and then selects three points in the A region, which is a large slope region of the VT curve of FIG. Interpolate by the cubic equation used. In addition, the control unit 300 interpolates by using a quadratic equation using two points in the B region and the C region, which are regions in which the slope is small in the V-T curve.

As a result, the controller 300 generates an ideal target V-T curve and generates a gamma reference voltage based on the generated target V-T curve.

In addition, the controller 300 stores the generated gamma reference voltage in the storage 400. The storage unit 400 is a storage device included in the liquid crystal display module 600 or a storage device in a production system of the liquid crystal display module. In this case, the storage device in the liquid crystal display module 600 is an EEPROM or a timing controller.

The gamma voltage generator 500 receives a gamma reference voltage from the storage 400 and provides the gamma reference voltage to the liquid crystal display module 600.

Accordingly, the data driver 630 in the liquid crystal display module 600 converts an image signal input from the outside into a corresponding gamma voltage by using the gamma reference voltage and provides it to the display panel 610. Accordingly, the display panel 610 displays an image corresponding to the image signal.

As described above, the present invention generates a VT curve according to interpolation using the luminance signal measured in part rather than measuring the luminance in all the change regions of the test signal, and generates a gamma reference voltage based on the generated VT curve. The time for gamma correction can be shortened.

Referring to the gamma control method of the gamma control device according to the invention in more detail as follows.

3 is a flowchart for performing a gamma adjusting method by the gamma adjusting apparatus shown in FIG. 1.

Referring to FIG. 3, the luminance measuring unit 200 measures the luminance of the liquid crystal display module 600 by the test signal TS (S700). Here, the test signal TS is a voltage signal.

The luminance measuring unit 200 measures luminance only in some regions of the change region of the test signal TS. For example, when 8-bit test data is input, luminance is measured only in 24 to 27 areas of 256 change areas.

Subsequently, the controller 300 generates a V-T curve by interpolating the luminance signal and the test signal TS measured by the luminance measuring unit 200 (S710). The controller 300 schematically generates a VT curve by the measured luminance signal, and then interpolates using a cubic equation in a region where the slope of the schematically generated VT curve is relatively large (region A of FIG. 2). . In addition, the controller 300 interpolates using a quadratic equation in a region (B and C regions of FIG. 2) where the slope of the roughly generated V-T curve is relatively small. As a result, the controller 300 generates an ideal target V-T curve.

The controller 300 generates a gamma reference voltage based on the generated target V-T curve (S720). That is, since source data of gamma data is a voltage, gamma reference voltage data may be generated by the target V-T curve.

As described above, the present invention generates the target V-T curve through interpolation after measuring the luminance in only a partial region instead of measuring the luminance in all regions where the test signal changes. Therefore, the time for gamma adjustment is shortened.

Figure 4 is a block diagram showing a gamma adjusting device according to another embodiment of the present invention. However, the same reference numerals are given to the same components as those shown in FIG. 1, and detailed description thereof will be omitted.

Referring to FIG. 4, the gamma adjusting device according to another embodiment of the present invention includes a test signal providing unit 100, a luminance measuring unit 200, a controller 900, which provides a test signal to the liquid crystal display panel 800. The first storage unit 910, the second storage unit 920, and the gamma voltage generator 500 are included.

The liquid crystal display module 800 includes a display panel 810, a data driver 620, and a gate driver 630 that provide driving control signals for displaying an image on the display panel 810.

The display panel 810 includes a plurality of gate lines GL1 to GLm and a plurality of data lines DL1 to DLn formed to cross the plurality of gate lines GL1 to GLm. The pixel PA is defined by two adjacent gate lines and data lines among the plurality of gate lines GL1 to GLm and the plurality of data lines DL1 to DLn. In the present exemplary embodiment, the pixel PA includes a main pixel area 812 and a sub pixel area 814. In this case, gamma voltages having different levels are provided to the main pixel region 812 and the sub pixel region 814.

The gate driver 620 sequentially supplies gate driving signals to the plurality of gate lines GL1 to GLm. The data driver 630 supplies an image signal corresponding to the test signal TS to the plurality of data lines DL1 to DLn in synchronization with a gate signal. As a result, an image is displayed on the display panel 810.

The luminance measuring unit 200 measures the luminance of the liquid crystal display module 800. The luminance measuring unit 200 measures only some of the change areas of the test signal TS. For example, when an image generated by an 8-bit test signal TS is displayed on the display panel 810, luminance is measured only in about 24 to 27 areas out of 256 areas that are change areas of the test signal TS. do.

In addition, the luminance measuring unit 200 measures the luminance of the main pixel region 812 and the sub pixel region 814 of the liquid crystal display module 800.

The controller 300 generates a first gamma reference voltage and a second gamma reference voltage using the luminance signal and the test signal TS provided from the luminance measuring unit 200. The first gamma reference voltage is for displaying an image in the main pixel region 812, and the second gamma reference voltage is for displaying an image in the sub pixel region 814.

More specifically, the controller 900 generates a VT curve as shown in FIG. 2 by using the measured luminance signal and the test signal TS, and then selects three points in the region A, which is a large slope region of the VT curve of FIG. Interpolate by the cubic equation used. In addition, the control unit 300 interpolates by using a quadratic equation using two points in areas B and C, which are areas in which the slope is small in the V-T curve.

As a result, the controller 900 generates an ideal target V-T curve and generates first and second gamma reference voltages by using the generated target V-T curve.

In addition, the controller 900 stores the generated first gamma reference voltage in the first storage unit 910 and stores the second gamma reference voltage in the second storage unit 920.

The gamma voltage generator 500 receives a gamma reference voltage from the first and second storage units 910.920, and provides the first and second gamma reference voltages to the liquid crystal display module 800.

Accordingly, the data driver 630 in the liquid crystal display module 800 converts an image signal input from the outside into a corresponding gamma voltage by using the first and second gamma reference voltages, respectively, and provides them to the display panel 810. Accordingly, the display panel 810 displays an image corresponding to the image signal.

As described above, the present invention generates a VT curve according to interpolation using the luminance signal measured in part rather than measuring the luminance in all the change regions of the test signal, and generates a gamma reference voltage based on the generated VT curve. The time for gamma correction can be shortened.

In addition, since the gamma correction time for gamma correction corresponding to the main pixel area and the sub pixel area is shortened, the present invention can effectively reduce the time for gamma correction.

FIG. 5 is a graph illustrating gamma voltage versus luminance characteristics adjusted by the gamma adjusting device shown in FIG. 4.

In FIG. 5, the first graph a shows gray vs. luminance characteristics in the main pixel region, the second graph b shows gray vs. luminance characteristics in the sub pixel region, and the third graph c shows the second graph. When an image is displayed on a liquid crystal display panel having the same characteristics as those of the first and second graphs (a and b), gray to luminance characteristics recognized by a human are displayed. That is, as shown in the third graph (c), the person recognizes the image in the middle region of the first and second grates (a and b).

As described above, the present invention measures the luminance in a partial region of the voltage change region, which is the source data of gamma data, generates a VT curve by interpolating the measured luminance, and then generates a gamma reference voltage using the generated VT curve. do.

Accordingly, the present invention can shorten the time for gamma correction by measuring the luminance in only a part of the voltage change region and interpolating to generate a V-T curve and generating a gamma reference voltage by the V-T curve.

In addition, the present invention can perform the gamma correction of the liquid crystal display device having the main pixel area and the sub pixel area more quickly by the above method.

Although the present invention has been described with reference to the embodiments, those skilled in the art may variously modify and change the present invention without departing from the spirit and scope of the invention as set forth in the claims below. You will understand.

Claims (12)

a test signal providing unit providing n test signals to the display unit; A luminance measuring unit measuring luminance of the display unit corresponding to m (natural numbers smaller than n) test signals among the n test signals; A controller configured to generate a gamma reference voltage using the m test signals and the measured luminance signals; A storage unit to store the gamma reference voltage; And And a gamma voltage generator for generating a gamma voltage in response to the stored gamma reference voltage when the image is displayed on the display unit. The gamma adjusting device of claim 1, wherein the test signal is a voltage signal. The method of claim 1, wherein the control unit interpolates the gamma reference voltage using a cubic equation in a region where the change in luminance according to the test signal is relatively large, and the change in luminance according to the test signal is relatively increased. And a gamma control device for interpolating the gamma reference voltage using a quadratic equation in a small region. The gamma adjusting device of claim 1, wherein the display unit includes a plurality of pixels having a main pixel area and a sub pixel area. The gamma adjusting device of claim 4, wherein the luminance measuring unit measures a luminance of the main pixel region to generate a first luminance signal, and measures a luminance of the sub pixel region to generate a second luminance signal. . The method of claim 5, wherein the controller is further configured to generate a first gamma reference voltage using the first luminance signal and the m test signals, and to generate a second gamma reference using the second luminance signal and the m test signals. Gamma regulator, characterized in that for generating a voltage. The method of claim 6, wherein the storage unit A first storage unit to store the first gamma reference voltage; And And a second storage unit for storing the second gamma reference voltage. providing n test signals to the display unit; Measuring luminance of the display unit corresponding to m test signals (m is a natural number smaller than n) among the n test signals; Generating a gamma reference voltage using the measured luminance signal and the m test signals; Storing the gamma reference voltage; And And generating a gamma voltage using the stored gamma reference voltage and providing the gamma voltage to the display unit. The method of claim 8, wherein the test signal is a voltage signal. The method of claim 9, wherein the display unit has a plurality of pixels each having a main pixel area and a sub pixel area. The method of claim 10, wherein the measuring of the luminance comprises: And controlling the luminance of the main and sub pixel regions to output first and second luminance signals. The method of claim 11, wherein the generating of the gamma reference voltage comprises: Generating a first gamma reference voltage using the first luminance signal and the m test signals; And And generating a second gamma reference voltage using the second luminance signal and the m test signals.

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