KR20230001540A - Voltage drop compensation system of display panel, and display driving device for compensating for voltage drop of display panel - Google Patents

Abstract

A voltage drop compensation system and a display driving device for compensating for a voltage drop of a display panel. The voltage drop compensation system generates a voltage drop compensation value for each of a plurality of regions into which a test image of a panel is divided, and the display driving device compensates for a voltage drop for each region of image data using the voltage drop compensation value.

Description

Voltage drop compensation system of display panel and display driving device for voltage drop compensation of the display panel

The present invention relates to a technology for compensating for a voltage drop of a display panel, and more particularly, to a voltage drop compensation system and a display driving device for compensating for the voltage drop of a display panel.

In general, a plurality of pixels are arranged in a matrix form on a panel of an active flat panel display device, and each pixel includes a thin film transistor (TFT) for switching an applied voltage and an electro-optical conversion element for converting an electrical signal into light. provide

A display device displays an image by controlling the luminance of each pixel expressed through an electro-optical conversion element according to given luminance information.

A plurality of voltage lines for transmitting a driving voltage and pixels driven by the driving voltage are formed on a panel of a display device. The driving voltage may be unevenly transferred to each pixel on the panel according to the position of the pixels due to the resistance of the voltage line and the RC delay.

That is, the voltage drop (IR-drop) of the driving voltage may occur differently for each position of the pixels. A voltage drop may increase as a pixel is farther away from a panel driver that provides a driving voltage, and thus power supply to the pixel may become unstable.

Therefore, the luminance of the pixels in the display device may become non-uniform due to a difference in voltage drop depending on the location of the pixels on the panel.

SUMMARY OF THE INVENTION The present invention is to overcome the above-described problems, and an object of the present invention is to improve non-uniformity of luminance for each position on a screen by compensating for a voltage drop that may vary for each position of pixels on a panel.

In addition, an object of the present invention is to improve luminance of pixels by compensating for MURA and voltage drop occurring in a panel.

An embodiment provides a voltage drop compensation system. The voltage drop compensation system includes an image receiver dividing a test image of a panel into a plurality of regions using image signals; a luminance value generating unit generating detected luminance values for each of the plurality of regions; and a voltage drop compensation value generator configured to compare the detected luminance value with a preset target luminance value and generate a voltage drop compensation value for a region where a voltage drop occurs among the plurality of regions, wherein the target luminance value is the plurality of regions. may be a luminance value of a region selected as a target region among regions of , and the voltage drop compensation value may be a difference between the detected luminance value and the target luminance value.

In addition, the embodiment provides a display driving device for compensating for a voltage drop of a display panel. Such a display driving device includes a voltage drop compensation value storage unit for storing voltage drop compensation values for each area in which a panel is divided; and a voltage drop compensation unit that receives image data and the voltage drop compensation value and generates voltage drop compensation data obtained by applying the voltage drop compensation value to the image data corresponding to each of a plurality of regions.

The present invention has an effect of securing uniformity of luminance for each position on a screen by compensating for a voltage drop that may occur differently for each position of a pixel of a panel.

In addition, the present invention has an effect of improving luminance of pixels by compensating for mura or voltage drop, and displaying a screen with a uniform luminance.

1 is a block diagram showing an embodiment of a voltage drop compensation system for a display panel according to the present invention.
Figure 2 is a block diagram of the compensating device of Figure 1;
3 is a diagram illustrating division of an image of a panel.
4 is a diagram for explaining setting a target luminance value and a detected luminance value.
FIG. 5 is a graph showing changes in detected luminance values on the y-axis line DY of FIG. 4 .
FIG. 6 is a graph showing voltage drop compensation values corresponding to the detected luminance values of FIG. 5 .
7 is a block diagram showing an embodiment of a display driving device according to the present invention.
8 is a graph for explaining interpolation using a quadratic equation.
9 is a graph for explaining piece-wise interpolation.
10 is a graph showing detected luminance values and voltage drop compensation values corresponding to image data.
11 is a graph showing luminance by voltage drop compensation data.
12 is a graph showing detected luminance values and voltage drop compensation values corresponding to image data when there is mura.
13 is a graph illustrating luminance according to voltage drop compensation data when there is mura.
14 is a graph illustrating luminance corresponding to Mura compensation data in which Mura is compensated for.
15 is a flowchart illustrating a voltage drop compensation method according to an embodiment.

The voltage drop compensation system of the present invention may be implemented as shown in FIG. 1, and an embodiment of the voltage drop compensation system of the present invention will be described with reference to FIG.

The voltage drop compensation system 1 is for generating a voltage drop compensation value for compensating for a voltage drop (IR-drop) that occurs differently for each location of pixels on the panel 20 .

To this end, the voltage drop compensation system 1 may be implemented to include a test image supply device 10 , a photographing device 30 and a compensation device 40 .

The voltage drop compensation system 1 configured as described above may display a test image on the panel 20 by the test image signal St and capture the test image displayed on the panel 20 .

Here, an image displayed on the panel 20 by the test image signal St may be defined as a test image, and an image obtained by capturing the test image may be defined as a test image.

The voltage drop compensation system 1 may divide the captured test image, detect luminance of each of a plurality of blocks in which the test image is divided, and generate a detected luminance value for each block.

The voltage drop compensation system 1 compares a detected luminance value and a preset target luminance value for each block and generates a comparison result.

The voltage drop compensation system 1 may determine the occurrence and degree of voltage drop for each block using the comparison result.

The voltage drop compensation system 1 may generate a voltage drop compensation value for a block in which a voltage drop occurs by using a comparison value generated as a comparison result. The voltage drop compensation value is a value for compensating for a driving voltage to be provided to the pixels of a block in which a voltage drop occurs in the panel 20, and the panel driver 100 providing the driving voltage to the panel 20 (FIG. 3) Reference) can be understood as being used to compensate for image data.

A detailed method of generating a voltage drop compensation value for the voltage drop compensation system 1 to compensate for the voltage drop will be described later.

For convenience of explanation, it is shown that the test image taken of the panel 20 is divided into a plurality of rectangular blocks, but the embodiment is not limited thereto, and the block is a predetermined number including a circle, an ellipse, and the like. may be a region. Hereinafter, in the examples, a block means an area.

In the embodiment, the voltage drop means a phenomenon in which the driving voltage provided to the pixels of the panel 20 from the panel driver 100 becomes unstable due to the influence of the resistance of the voltage line and the RC delay, and the pixels of the panel 20 It may occur differently depending on the distance between the and the panel driving unit 100 .

A more specific configuration and operation of the voltage drop compensation system 1 described above will be described.

The test image supply device 10 may supply a test image signal St for displaying the test image on the panel 20 .

The voltage drop may appear differently for each Display Brightness Value (hereinafter referred to as “DBV”), for each gradation value, and according to the characteristics of the panel 20 .

The test image supply device 10 pre-stores test data for each DBV and each gradation value set in advance for a test, and sends a test image signal St corresponding to the selected test data to the panel 20 to display the test image. can provide In this case, the test image supply device 10 may sequentially provide test image signals St corresponding to test data for each DBV and each grayscale value.

A test image for measuring luminance may be displayed on the panel 20 corresponding to the test image signal St.

Assuming that there is no voltage drop across the panel 20, the test image signal St may be provided for each of a plurality of DBVs, eg, 200 nit, 420 nit, and 800 nit, respectively.

In addition, assuming that there is no voltage drop across the panel 20, the test image signal St may be provided for each of a plurality of gray levels, for example, based on 32 gray levels, 64 gray levels, and 128 gray levels.

That is, the test image signal St may be provided to correspond to test data corresponding to a specific DBV and a specific grayscale value.

Meanwhile, the panel 20 includes a plurality of pixels arranged in a matrix form, and may display a test image according to the test image signal St.

More specifically, the panel 20 may display a test image corresponding to a specific gray level and a specific DBV according to the test image signal St. For example, the panel 20 may display test images for each DBV based on a first gray level, a second gray level, or a third gray level according to the test image signal St. The first gray level, the second gray level, and the third gray level may be selected by a producer from among a predetermined gray level range, for example, 0 to 255 gray levels, and may be exemplified by 32 gray levels, 64 gray levels, and 128 gray levels, and test images. The signal St may be provided to correspond to the grayscale value of the selected grayscale.

As described above, the voltage drop may occur differently even in the same pixel according to each DBV, each input grayscale value, and the unique characteristics of the panel 20 . Also, voltage drop may occur differently in a direction away from the panel driving unit (100 in FIG. 3 ) (in the direction of the arrow in FIG. 3 ) corresponding to a distance between the pixels and the panel driving unit 100 . In this case, the panel 20 may be an LCD panel or an OLED panel used in a mobile device, but the embodiment is not limited thereto.

In addition, the panel 20 may display an image to have Mura, in which luminance is non-uniformly displayed due to characteristics of pixels. Mura refers to a phenomenon in which a certain area of the panel 20 is displayed with non-uniform luminance due to problems such as defects in pixels. In this case, the panel driver 100 providing the driving voltage to the panel 20 needs to compensate for image data so as to compensate not only the voltage drop but also the luminance of the panel 20 due to Mura. A specific method for compensating for voltage drop and Mura will be described later.

The photographing device 30 may photograph part or all of the panel 20 displaying the test image and generate an image signal Si for the test image of the panel 20 . The photographing device 30 may be configured using a camera for measuring luminance of a test image. For example, the photographing device 30 may include a luminance meter capable of measuring the luminance of a display device such as a liquid crystal (LCD), a PDP, an organic EL (OLED), or a rear projector, but the embodiment is limited thereto It is not.

Illustratively, the photographing device 30 may sequentially capture test images corresponding to the first, second, and third gray levels of the same DBV sequentially displayed on the panel 20, and the corresponding The first image signal Si1, the second image signal Si2, and the third image signal Si3 may be sequentially generated and provided.

In addition, the photographing device 30 may sequentially capture test images corresponding to the first DBV, the second DBV, and the third DBV of the same grayscale sequentially displayed on the panel 20, and the first image corresponding thereto. The signal Si1, the second image signal Si2, and the third image signal Si3 may be sequentially generated and provided.

The compensation device 40 may receive an image signal Si obtained by capturing the panel 20 and divide a test image corresponding to the image signal Si into a plurality of blocks BL.

In addition, the compensation device 40 may generate a detected luminance value by detecting the luminance value for each block BL. In this case, the detected luminance value of the block BL may be generated as a value representing the luminance values of the pixels included in the block BL. For example, the detected luminance value is the luminance value of the pixels included in the block BL. It can be set as the average value of

And, the compensating device 40 may store a preset target luminance value.

The compensating device 40 may generate a comparison value as a comparison result of comparing the detected luminance value and the target luminance value for each block, and may detect blocks in which a voltage drop occurs among a plurality of blocks by using the comparison value.

The compensation device 40 may calculate a value for changing the detected luminance value, that is, a voltage drop compensation value to compensate for the voltage drop of the block where the voltage drop occurs. The compensation device 40 may store the voltage drop compensation value generated by the calculation as described above.

Hereinafter, the configuration and operation of the compensating device 40 of FIG. 1 will be described in detail with reference to FIG. 2 .

The compensation device 40 may include an image receiver 410, a luminance value generator 420, a compensation value generator 430, and a compensation value storage unit 440.

The image receiving unit 410 receives an image signal Si corresponding to a test image obtained by photographing the test image of the panel 20 by the photographing device 30, and converts the test image of the panel 20 into a plurality of blocks BL. can be divided into Also, the image receiving unit 410 may provide the image signal Si and location information for each block BL.

The luminance value generator 420 receives the image signal Si and location information for each block BL from the image receiver 410, and detects each block BL using the image signal Si for each block BL. A luminance value can be created. That is, the luminance value generator 420 may generate detected luminance values for each block BL in correspondence to the image signal Si for each gray level value of the DBV set in advance.

Exemplarily, the luminance value generator 420 may generate a detected luminance value for each block BL using the first image signal Si1 for each block BL corresponding to the first grayscale, and may generate a detected luminance value for each block BL corresponding to the first grayscale, and A detected luminance value for each block BL may be generated using the second image signal Si2 for each block BL corresponding to the block (BL) using the third image signal Si3 corresponding to the third gray level. BL) may generate a detected luminance value for each star.

The luminance value generator 420 may provide the detected luminance value and location information for each block to the compensation value generator 430 .

The compensation value generator 430 may receive the detected luminance value and location information for each block from the luminance value generator 420 and generate a voltage drop compensation value Virc for each block BL. A detailed method of generating the voltage drop compensation value Virc by the compensation value generator 430 will be described later.

The compensation value generator 430 may provide the voltage drop compensation value Virc and location information for each generated block BL to the compensation value storage unit 440 .

The compensation value storage unit 440 may store the voltage drop compensation value Virc in the form of a look-up table in units of blocks using location information. In this case, the compensation value storage unit 440 may store the voltage drop compensation value Virc to be classified according to DBV and gradation value for the same block.

Hereinafter, with reference to FIG. 3 , a detailed method of dividing a test image of the panel 20 taken by the image receiving unit 410 into a plurality of blocks BL will be described.

The image receiving unit 410 may divide a test image obtained by taking a test image of the panel 20 into a plurality of blocks BL using the image signal Si corresponding to a specific DBV and a specific gray level, and each of the divided blocks BL. Position information on the block BL of may be generated.

For example, the image receiving unit 410 receives an image signal Si for a test image from the photographing device 30, divides the test image into 4X8 blocks BL, and divides the test image into 4X8 blocks BL, and provides position information for each of the 4X8 blocks BL. can create In FIG. 3 , it can be seen that divided blocks are exemplified by b11 to b84. In FIG. 3 , BLs representing blocks may be understood to represent blocks included in the test image of the panel 20 .

Although the embodiment has been described as dividing the test image of the panel 20 into 4X8 blocks BL by the image receiving unit 410 for convenience of description, the present invention is not limited thereto. For example, if the size of the panel 20 is 1080X2400, the test image can be theoretically divided into 1080X2400 blocks, and as another example, the test image can be divided into 270X600 blocks.

Hereinafter, a specific method for generating the voltage drop compensation value Virc by the compensation value generating unit 430 will be described with reference to FIGS. 4 to 6 .

The compensation value generation unit 430 may generate a voltage drop compensation value Virc for each block BL using the target luminance value. The compensation value generation unit 430 may select a center of the panel 20 or an arbitrary block closest to the center of the plurality of blocks BL as a target block and set a detected luminance value of the target block as the target luminance value. In the case of FIG. 4 , a block b42 among a plurality of blocks may be selected as a target block, and a sensed luminance value of the block b42 may be set as the target luminance value.

The compensation value generator 430 may receive detected luminance values of the plurality of blocks BL and location information from the luminance value generator 420 . The compensation value generation unit 430 compares the target luminance value and the detected luminance value for each block BL, and if there is a difference between the target luminance value and the detected luminance value, it may be determined that a voltage drop has occurred in the corresponding block BL. there is.

In FIG. 4 , DY may be understood to indicate a y-axis line including the block b42 selected as the target block. Here, the y-axis line DY may be understood as a direction in which a driving voltage is transmitted from the panel driver 100 through the panel 20, and the voltage drop varies depending on the position of the block on the y-axis line DY. can happen

For example, the voltage drop on the y-axis line DY may occur at different levels depending on the positions of the blocks BL, as shown in FIG. 5 .

FIG. 5 is a graph showing a correlation between luminance and distance D, and represents detected luminance values that vary according to positions of blocks on the y-axis line DY of FIG. 4 .

In FIG. 5 , L0 , L1 , and L2 denote detected luminance values, and D0 , D1 , and D2 denote distances between blocks from the panel driver 100 . Illustratively, it can be understood that the block b42 selected as the target block has a detected luminance value of L0 at the position of D0. At this time, L0 may be understood as a target luminance value.

In FIG. 5, Ls represents the change curve of the detected luminance value on the y-axis line DY of FIG. It can be understood as a detected luminance value of any block of , and corresponds to the lowest luminance value of the curve Ls. L2 may be understood as a detected luminance value of an arbitrary block at a position D2 closer to the panel driver 100 than the block b42 on the y-axis line DY, and corresponds to the highest luminance value of the curve Ls.

Accordingly, the compensation value generation unit 430 generates a block for blocks having different detected luminance values for each position, such as the y-axis line DY of FIG. 5, based on the target luminance value corresponding to the detected luminance value of the block b42. Voltage drop compensation values Virc may be generated.

The voltage drop compensation values Virc of the blocks BL can be understood as a difference between a target luminance value and a detected luminance value for each block. In the case of FIG. 5, the voltage drop compensation values Virc are similar to those of FIG. 6. can be created together.

That is, the compensation value generation unit 430 calculates the target luminance value L0 for each block BL and the blocks Bl in order to compensate the detected luminance value of the blocks BL with the target luminance value L0. It is possible to generate a voltage drop compensation value Virc by comparing the detected luminance values of . The compensation value generation unit 430 obtains a difference between the target luminance value L0 and the detected luminance values of the blocks Bl for each block BL as a comparison result, and the difference value is a voltage drop compensation value as shown in FIG. 6 ( Virc).

Referring to FIGS. 4 to 6 , in the embodiment of the present invention, obtaining the voltage drop compensation value Virc for the y-axis line DY where the block B42 is located has been described. However, the compensation value generation unit 430 calculates the target luminance value L0 corresponding to the detected luminance value of the block B42 and the detected luminance of the corresponding block for the remaining blocks other than the y-axis line DY by the above method. The difference between the values may be generated as voltage drop compensation values Virc.

As described above, the voltage drop compensation values Virc generated by the compensation value generator 430 may be stored in the compensation value storage unit 440 like location information.

The compensation value storage unit 440 can convert the voltage drop compensation values Virc into digital data and store them in the form of an axis-up table. It can be saved to match.

The voltage drop compensation values Virc stored in the compensation value storage unit 440 may be stored in the panel driver 100 for driving the panel 20 and may be used for voltage drop compensation of image data.

Hereinafter, the panel driving unit 100 according to the embodiment will be described with reference to FIG. 7 . The panel driving unit 100 of FIG. 7 may be understood as an embodiment of a display driving device for voltage drop compensation according to the present invention.

Referring to FIG. 7 , the panel driver 100 applies a voltage drop compensation value Virc in units of blocks BL to image data Din input from the outside, and then compensates for Mura occurring in the panel 20. By applying the compensation value Vmc, a video signal DS in which voltage drop and mura are compensated may be generated. The image signal DS may be understood as a driving voltage provided to the panel 20 .

The panel driver 100 includes a data receiving unit 110, a voltage drop compensation value storage unit 121, a voltage drop compensation unit 122, a Mura compensation value storage unit 131, a Mura compensation unit 132, and an image signal output unit. (140).

The data receiver 110 may receive image data Din input from the outside, restore and output the image data Din. The image data Din input to the data receiving unit 110 from the outside and the image data Din provided from the data receiving unit 110 to the voltage drop compensation unit 122 may have different formats. Accordingly, the data receiving unit 110 may perform a restoration operation to transfer the image data Din to the voltage drop compensation unit 122, and since the above restoration operation may be variously performed by a manufacturer, detailed description thereof is omitted.

The voltage drop compensation value storage unit 121 may store the voltage drop compensation value Virc. The voltage drop compensation value storage unit 121 may store the voltage drop compensation value Virc in a block BL unit in the form of a look-up table (LUT). The voltage drop compensation value Virc of the voltage drop compensation value storage unit 121 may be understood as storing the voltage drop compensation value Virc of the compensation value storage unit 440 of the compensation device 40. Since the voltage drop compensation value Virc in the compensation value storage unit 121 can be stored in the same way as the compensation value storage unit 440 of the compensation device 40, a description thereof will be omitted.

The voltage drop compensation unit 122 receives the image data Din from the data receiver 110 and receives the voltage drop compensation value Virc from the voltage drop compensation value storage unit 121 .

The voltage drop compensation unit 122 may generate voltage drop compensation data Dirc by applying the voltage drop compensation value Virc to the image data Din in units of blocks. Here, the voltage drop compensation data Dirc is obtained by compensating luminance by applying the voltage drop compensation value Virc to the image data Din for each block. That is, in order to compensate for the luminance difference due to the voltage drop for each block, the voltage drop compensation value Virc for each block is applied to the image data Din for each block, and the voltage drop compensation data Dirc is generated as a result of the application. can The voltage drop compensation unit 122 may generate the voltage drop compensation data Dirc by using the voltage drop compensation value Virc, that is, the compensation value, to adjust the gain of the image data Din.

In this case, the voltage drop compensation value Virc may be selected to correspond to the DBV applied to the image data Din and the gray level of the image data Din.

A more specific method of applying the voltage drop compensation data Dirc by the voltage drop compensation unit 122 according to the embodiment will be described later.

The Mura compensation value storage unit 131 may store a Mura compensation value Vmc for compensating for Mura occurring in the panel 20 . The Mura compensation value Vmc may be stored to have location information for each block or each pixel.

The mura compensator 132 is configured to receive the voltage drop compensation data Dirc of the voltage drop compensator 122 and the mura compensation value Vmc of the mura compensation value storage unit 131 . A detailed method of applying the Mura compensation value Vmc to the Mura compensator 132 will be described later.

The Mura compensator 132 may exemplarily compensate for Mura in units of blocks using the Mura compensation value Vmc.

To this end, the mura compensation unit 132 may generate mura compensation data Dmc by applying the mura compensation value Vmc for each block to the voltage drop compensation data Dirc. More specifically, the Mura compensator 132 may be configured to convert the voltage drop compensation value Virc into the Mura compensation value Vmc according to a preset Mura compensation equation. Therefore, the mura compensation unit 132 may generate mura compensation data Dmc obtained by applying the mura compensation value Vmc to the coefficient of the mura compensation equation and calculating the voltage drop compensation data Dirc according to the mura compensation equation. there is. The Mura compensation equation may be configured as a first-order, second-order, or multi-order equation by a manufacturer. The Mura compensation data Dmc may be understood as image data obtained by compensating for luminance of the voltage drop compensation data Dirc for Mura compensation.

The image signal output unit 140 may receive the Mura compensation data Dmc of the Mura compensator 132 and output an image signal DS corresponding to the Mura compensation data Dmc. The image signal DS of the image signal output unit 140 may be considered as having applied voltage drop compensation by the voltage drop compensator 122 and compensation for mura by the Mura floater 132 applied.

Therefore, the panel driving unit 100 of FIG. 7 according to the present invention can prevent a screen defect due to luminance change or mura caused by a voltage drop. Meanwhile, when Mura compensation is unnecessary, the manufacturer may configure the panel driver 100 to provide the voltage drop compensation data Dirc of the voltage drop compensation unit 122 to the image signal output unit 140. In this case, the video The signal output unit 140 may receive voltage drop compensation data Dirc and output an image signal DS corresponding to the voltage drop compensation data Dirc.

Meanwhile, in the embodiment, the voltage drop compensation value storage unit 121 stores a plurality of preset DBVs and voltage drop compensation values Virc corresponding to a plurality of gray levels, and the Mura compensation value storage unit 131 also stores a plurality of preset DBVs. It is possible to store the DBV of , and Mura compensation values Vmc corresponding to a plurality of gray levels.

Therefore, when the image data Din corresponds to a plurality of preset DBVs or a plurality of gradations, the voltage drop compensation unit 122 stores the voltage drop compensation values Virc stored in the voltage drop compensation value storage unit 121. Compensation of the image data Din can be performed by using.

However, when the image data Din corresponds to a plurality of DBVs applied to the voltage drop compensation values Virc of the voltage drop compensation value storage unit 121 or a DBV and a gray level among a plurality of gray levels, the voltage drop compensation unit ( 122) generates a voltage drop compensation value Virc for compensation of the image data Din by interpolation using the voltage drop compensation values Virc of the voltage drop compensation value storage unit 121, and Compensation of the image data Din may be performed using the voltage drop compensation values Virc generated by one interpolation.

The interpolation described above may use a quadratic approximation equation as shown in FIG. 8 or piece-wise interpolation as shown in FIG. 9 . In FIGS. 8 and 9 , voltage drop compensation values are indicated as compensation values.

Referring to FIG. 8 , the voltage drop compensation unit 122 sets a secondary approximation equation that satisfies the voltage drop compensation values for each gray level provided from the voltage drop compensation value storage unit 121, and uses the secondary approximation equation to obtain image data. A compensation value corresponding to the gradation of (Din) can be obtained. The compensation value obtained by the method of FIG. 8 may be used as the voltage drop compensation value Virc. In the case of FIG. 8 , it can be understood that voltage drop compensation values Virc corresponding to 32, 64, and 128 gray levels of the preset DBV are provided from the voltage drop compensation value storage unit 121 .

The voltage drop compensation unit 122 may obtain a voltage drop compensation value Virc of a different value by interpolation using the quadratic approximation equation for each DBV.

Meanwhile, referring to FIG. 9 , the voltage drop compensation unit 122 sets a section using the voltage drop compensation values for each gray level provided from the voltage drop compensation value storage unit 121, and sets the interval between the gray levels in which the voltage drop compensation values are stored. A linear expression expressing a change in the compensation value for each section is obtained, and a compensation value corresponding to the gray level of the image data Din can be obtained by piece-wise interpolation using the linear expressions for each section. The compensation value obtained by the method of FIG. 9 may be used as the voltage drop compensation value Virc. In the case of FIG. 9 , it can be understood that the voltage drop compensation value Virc corresponding to the preset 32 gradations, 64 gradations, and 128 gradations is provided from the voltage drop compensation value storage unit 121 .

The voltage drop compensation unit 122 may obtain a voltage drop compensation value Virc of a different value by the piece-wise interpolation for each DBV.

Voltage drop compensation of the panel driver 100 configured according to the embodiment of the present invention can be described with reference to FIGS. 10 and 11 .

Exemplarily, when the same DBV and image data Din of the same gray level are applied to all blocks on the y-axis line DY of FIG. 4 , luminance corresponding to the image data Din as shown in FIG. 10 The change in value can be displayed with the curve Lin by the voltage drop. Since the shape of the curve Lin in FIG. 10 can be understood with reference to FIG. 5, a detailed description thereof will be omitted.

The voltage drop compensation unit 122 receives the voltage drop compensation value Virc of the image data Din for each block from the voltage drop compensation value storage unit 121, and corresponds to the gradation of the image data Din of FIG. 10. A voltage drop compensation value Virc may be generated. When the luminance changes due to the voltage drop for each position of the block BL as in the curve Lin, the voltage drop compensator 122 may generate a voltage drop compensation value Virc as in the curve Virc. Since the curve Virc of FIG. 10 can be understood with reference to FIG. 6, a detailed description thereof will be omitted.

The voltage drop compensation unit 122 can compensate for the luminance change due to the voltage drop of the image data Din with the voltage drop compensation value Virc, and as a result, the same DBV and the same grayscale image data Din ), the luminance values of the blocks BL of the panel 20 may become uniform as shown in FIG. 11 regardless of positions.

In addition, voltage drop compensation and Mura compensation of the panel driver 100 configured according to the embodiment of the present invention can be described with reference to FIGS. 12 and 14 .

When voltage drop and mura affect the luminance of the blocks BL of the panel 20, the luminance values of the blocks BL corresponding to the image data Din may be exemplified as the curve Lin of FIG. 12 . there is. It can be understood that the curve Lin of FIG. 12 includes noise N caused by mura in the luminance change caused by the voltage drop in FIG. 10 .

As described above, when the voltage drop and Mura affect the luminance of the blocks BL of the panel 20, the panel driver 100 may perform voltage drop compensation and then Mura compensation.

The voltage drop compensation unit 122 may generate a voltage drop compensation value Virc corresponding to the gray level of the image data Din in order to compensate for a luminance change such as a curve Lin due to a voltage drop applied to the blocks. Since generation of the voltage drop compensation value Virc can be understood with reference to FIG. 10 , a detailed description thereof will be omitted.

The voltage drop compensation unit 122 may output voltage drop compensation data Dirc as shown in FIG. 13 by compensating the input data Din with the voltage drop compensation value Virc. At this time, since the voltage drop compensation data Dirc is not corrected for Mura, it includes noise N due to Mura. Since voltage drop compensation by the voltage drop compensator 122 can be understood with reference to FIGS. 10 and 11 , a detailed description thereof will be omitted.

The voltage drop compensation data Dirc of the voltage drop compensator 122 is provided to the Mura compensator 132, and the Mura compensator 132 may remove noise N caused by Mura.

More specifically, the Mura compensation value storage unit 131 stores the Mura compensation value Vmc designated for each block or each pixel, and the Mura compensation unit 132 stores the Mura compensation value Vmc for each block or each pixel of the Mura compensation value storage unit 131. Noise N caused by Mura included in the voltage drop compensation data Dirc of FIG. 13 may be removed using the Mura compensation value Vmc. The mura compensation unit 132 may generate the mura compensation data Dmc by applying the mura compensation value Vmc to a coefficient of a preset mura compensation equation.

As a result, the Mura compensator 132 may generate and output Mura compensation data Dmc of FIG. 14 in which the noise N caused by Mura is removed.

Hereinafter, a voltage drop compensation method implemented according to the present invention will be described in detail with reference to FIG. 15 . An embodiment of the voltage drop compensation method of FIG. 15 can be understood with reference to FIG. 2 .

In step S10, the image receiving unit 410 divides the image of the panel 20 into a preset number of blocks BL using the image signal Si, and provides position information of each of the divided blocks BL. can create

The detected luminance value corresponding to the image signal Si of each of the divided blocks BL may be generated by the luminance value generator 420 and transferred to the compensation value generator 430 . At this time, location information of the blocks BL may be delivered together with the sensed luminance value.

In step S20, the compensation value generating unit 430 may select an arbitrary block among the plurality of blocks BL as a target block and set the sensed luminance value of the target block as the target luminance value. For example, the compensation value generating unit 430 may select a target block b42 from among a plurality of blocks and set the detected luminance value of the target block b42 as the target luminance value.

In step S30, the compensation value generator 430 compares the target luminance value of the target block with the detected luminance values of the remaining blocks of the panel 20, and uses the difference between the target luminance value and the detected luminance value to block ( It is possible to determine the occurrence of a voltage drop in units of BL). When the detected luminance value is different from the target luminance value, the compensation value generator 430 may determine that a voltage drop corresponding to a difference between the detected luminance value and the target luminance value has occurred in the block BL.

In step S40 , the compensation value generation unit 430 may generate a plurality of voltage drop compensation values Virc so that the detected luminance values of the blocks BL become the target luminance value L0.

In step S50, the compensation value storage unit 440 may store the voltage drop compensation value Virc in the form of a lookup table in units of blocks BL.

As described above, the present invention can compensate for the voltage drop that may occur differently for each pixel position of the panel according to the embodiment, and as a result, uniformity of luminance displayed on the screen can be secured.

In addition, the present invention can compensate for the mura or voltage drop of the panel according to the embodiment, and as a result, the luminance of the pixels is improved, and the panel can display the screen with uniform luminance.

Claims (16)

an image receiving unit dividing a test image of the panel into a plurality of regions using image signals;
a luminance value generating unit generating detected luminance values for each of the plurality of regions; and
A voltage drop compensation value generator configured to compare the detected luminance value with a preset target luminance value and generate a voltage drop compensation value of a region where a voltage drop occurs among the plurality of regions;
The target luminance value is a luminance value of a region selected as a target region among the plurality of regions, and
The voltage drop compensation value is a difference between the detected luminance value and the target luminance value, the voltage drop compensation system of the display panel. According to claim 1,
The voltage drop compensation system of the display panel of claim 1 , wherein the luminance value generator generates an average luminance value of a plurality of pixels included in a preset target area as the target luminance value. According to claim 1,
The voltage drop compensation system of the display panel of claim 1 , wherein the compensation value generating unit sets one of a center area of the panel and an area closest to the center of the plurality of areas as the target area. According to claim 1,
The location information of the area is transmitted from the image receiver to the luminance value generator and the voltage drop compensation value generator,
The voltage drop compensation value is set such that the sensed luminance value is equal to the target luminance value. According to claim 1,
The image receiving unit receives the image signals corresponding to a plurality of gray levels and a plurality of DBVs, and outputs image signals and position information for each of a plurality of regions obtained by dividing the test image;
The luminance value generating unit receives the image signal and the location information, generates the detected luminance values for each region of the test image corresponding to the plurality of gray levels and the plurality of DBVs, and generates the detected luminance values for each region. And outputting the location information,
The voltage drop compensation value generating unit receives the detected luminance value and the location information, sets the target luminance value of the test image corresponding to the plurality of gray levels and the plurality of DBVs, and sets the plurality of gray levels and the plurality of DBVs. The voltage drop compensation system of a display panel, wherein the voltage drop compensation value is generated by comparing the target luminance value and the detected luminance value for each region of the test image corresponding to a DBV of . According to claim 5,
Further comprising a compensation value storage unit including a lookup table,
wherein the compensation value storage unit stores the voltage drop compensation values corresponding to the plurality of gray levels and the plurality of DBVs for each region in the look-up table. a voltage drop compensation value storage unit that stores voltage drop compensation values for each area in which the panel is divided; and
and a voltage drop compensation unit for receiving image data and the voltage drop compensation value and generating voltage drop compensation data obtained by applying the voltage drop compensation value to the image data corresponding to each of a plurality of regions. drive. According to claim 7,
The voltage drop compensation value corresponds to a difference between a target luminance value and a detected luminance value of the plurality of regions;
The display driving device of claim 1 , wherein the target luminance value is set to a detected luminance value of a target area in which one of a center area of the panel and an area closest to the center is selected. According to claim 8,
The target luminance value is an average luminance value of a plurality of pixels included in the target area. According to claim 9,
The voltage drop compensation value storage unit stores the voltage drop compensation value for each region corresponding to the plurality of gray levels and the plurality of DBVs;
The voltage drop compensation unit receives the voltage drop compensation value corresponding to the gray level and DVB of the image data. According to claim 10,
The voltage drop compensation unit receives the voltage drop compensation value corresponding to the gray level and DVB of the image data from the voltage drop compensation value storage unit, and applies a compensation value generated by interpolating the received voltage drop compensation value. and generating the voltage drop compensation data corresponding to the gray level and the DBV of the image data. According to claim 11,
The voltage drop compensation unit generates the compensation value by the interpolation using a quadratic approximation equation. According to claim 11,
The voltage drop compensation unit generates the compensation value by piece-wise interpolation. According to claim 11,
The voltage drop compensation unit generates the voltage drop compensation data by using the compensation value for gain control. According to claim 7,
a Mura compensation value storage unit to store a Mura compensation value of the panel; and
A Mura compensation unit generating Mura compensation data by applying the Mura compensation value to the voltage drop compensation data;
The Mura compensation data is image data in which the Mura is compensated for. According to claim 15,
The Mura compensation value is
A Mura compensation value for compensating for at least one of a Mura region and a Mura pixel of the panel;
wherein the mura compensation unit generates the mura compensation data by applying the mura compensation value to a coefficient of a preset mura compensation equation.

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