KR20060130231A - Gamma correction circuit, display panel, and display having them - Google Patents

Abstract

A display having a display panel the color balance of which can be adjusted. The display (1) comprises a gamma correcting circuit (5a) including a gamma data output circuit (11a) for outputting gamma correction data for each color of RGB, registers (12 1 to 12m) receiving and holding the gamma correction data, and D/A converters (DAC) (131 to 13m) for converting the data in the registers (121 to 12m) into analog voltages and outputting gamma correction setting voltages VI1 to VIm, a source driver (6) receiving image data, selecting gamma correction setting voltages or their interpolation voltages in accordance with the image data, and thereby outputting a corrected image voltage, and a display panel (7) in which gate lines are connected to display elements each displaying one color are driven by a gate driver (8) and the corrected image voltage from the source driver (6) is inputted into a source line.

Description

Gamma correction circuit, display panel, and display device having them {GAMMA CORRECTION CIRCUIT, DISPLAY PANEL, AND DISPLAY HAVING THEM}

The present invention relates to a gamma correction circuit and a circuit display panel. The present invention also relates to a display device such as a liquid crystal display device including a gamma correction circuit and a display panel.

Generally, in the display panel of display apparatuses, such as a liquid crystal display device, it has a nonlinear correlation, ie, gamma characteristic, between the applied voltage of a display element and brightness | luminance. 5 shows general gamma characteristics. Curve A of the solid line in FIG. 5 is a characteristic of the display element of the liquid crystal (ie, gamma characteristic) when the applied voltage is set as it is without correction (gamma correction) of the image voltage (for example, V ₁ or V _m ). )to be. In the same figure, the horizontal axis is applied voltage, and the vertical axis is relative luminance (i.e., light transmittance of liquid crystal). Now, the image voltage (for example, V ₁ Alternatively, if V _m ) is applied as it is without gamma correction, a good image cannot be displayed because it follows this nonlinear correlation. Therefore, in order to display a good image, a corrected image voltage (e.g., V ₁ or V _m ) obtained by gamma-correcting the image voltage (e.g. For example, VI ₁ or VI _m ) is applied as the applied voltage.

Thus, as the gamma correction circuit which performs gamma correction in a liquid crystal display device, what was disclosed by patent documents 1, 2, and 3 is known, for example. Moreover, the applicant of this application proposes the gamma correction circuit in patent document 4 which made the background art what was disclosed by these patent documents. 6, the liquid crystal display device containing the same gamma correction circuit as patent document 4 is shown. The liquid crystal display 101 inputs a gamma correction circuit 105a for outputting gamma adjustment setting voltages VI ₁ to VI _m , and n-bit (eg, 8-bit) image data Di, and corresponding gamma. A source driver 6 for outputting the corrected image voltage V _O as an applied voltage for each of its source lines by selecting the correction setting voltages VI ₁ to VI _m or their interpolation voltages to be described later; A display panel 107, a gate driver 8 for driving the gate line of the display panel 107, and a nonvolatile memory 109 for storing gamma correction data.

The gamma correction circuit 105a converts the gamma correction data of the serial input via the input terminal SD from the outside into L bit (for example, 10 bits) parallel, which is digital data corresponding to the gamma correction setting voltages VI ₁ to VI _m . and the gamma correction data output circuit (111a) that converts to gamma correction data, by entering the gamma correction data in the parallel holding (holding) m pieces (for example, nine), the register (12 ₁ to 12 _m to ), A 10-bit D / A converter (DAC) 13 ₁ to 13 _m for converting data output by the registers 12 ₁ to 12 _m into an analog voltage, and a D / A converter (DAC). (13 ₁ to 13 _m ) inputs an analog voltage output, and includes a buffer (14 ₁ to 14 _m ) for increasing the current capability to output the gamma correction set voltage VI ₁ to VI _m . Further, the gamma correction data output circuit 111a stores the gamma correction data in the nonvolatile memory 109 and extracts it from the nonvolatile memory 109 as necessary.

The source driver 6 is the gamma correction setting voltage VI ₁ which is the output of the gamma correction circuit 105a. To voltage between the adjacent in VI _m (e.g., between a VI ₁ and VI ₂₎ the m 'evenly as resistors interpolation (補間) and of the resistance rudder (15) for generating an interpolation voltage, n-bit And a decoder 16 for selecting gamma correction setting voltages VI ₁ to VI _m or their interpolation voltages according to the image data Di to output the corrected image voltage V _O. The display panel 107 for inputting the corrected image voltage Vo has a gray scale of 2 ⁿ . That is, when n is 8, the gray level of the display panel 107 is 256. In addition, the value of m 'is calculated | required by ²ⁿ / (m-1). In other words, if n is 8 and m is 9, m 'is 32. For example, if the value of the image data Di is 0, the corrected image voltage Vo is the same voltage as VI _1, and if the value of the image data Di is 16, the corrected image voltage Vo is the voltage at the center of VI ₁ and VI ₂ . do.

During adjustment, the display of the display panel 107 is confirmed in real time, and the gamma correction setting voltages VI ₁ to VI _m are reduced by inputting the gamma correction data of the serial to the gamma correction circuit 105a through the input terminal SD from the outside. It is adjusted to be appropriate. When the adjustment is completed, the gamma correction data in the adjustment completed state is stored in the nonvolatile memory 109, and after that, the gamma correction data stored in the nonvolatile memory 109 is used.

Next, the liquid crystal display device which has a component similar to the other embodiment in patent document 4 is shown in FIG. The liquid crystal display device 102 has a source driver 6, a display panel 107, a gate driver 8, and a nonvolatile memory 109 having substantially the same circuit configuration or structure as the liquid crystal display device 101 described above. And a gamma correction circuit 105b having a different configuration from that of the gamma correction circuit 105a. The gamma correction circuit 105b includes two sets of m registers for holding the gamma correction data output circuit 111b and data corresponding to the odd / even numbers of the horizontal line (horizontal scan line) of the display parallel 107. (12 ₁ a to 12 _m a, 12 ₁ b to 12 _m b), and a selector which selects one of the sets to be switched and output to the D / A converters 13 ₁ to 13 _m described later ( 117 ₁ to 117 _m ) and the horizontal synchronization signal HS, which is a synchronization signal of the horizontal line of the display panel 107, are input, and switching control of the selector 117 ₁ to 117 _m is performed according to the odd / even number of the horizontal line. And a selector control circuit 118, a D / A converter 13 ₁ to 13 _m , and a buffer 14 ₁ to 14 _m . This gamma correction circuit 105b is adapted to the function of the gamma correction circuit 105a. In addition, the gamma correction setting voltage VI ₁ to VI _m can be changed at high speed according to the odd / even number of horizontal lines. It is suitable for a driving method of a line reversal method for reversing the polarity of the government in horizontal lines above and below the plane.

Next, the liquid crystal display device which has the same component as another embodiment in patent document 4 is shown in FIG. The liquid crystal display 103 is a source driver 6, a display panel 107, a gate driver 8, and a nonvolatile memory 109 having substantially the same circuit configuration or the same structure as the liquid crystal display devices 101 and 102. ), And instead of gamma correction circuits 105a and 105b, it includes a gamma correction circuit 105c different in configuration. The gamma correction circuit 105c includes a gamma correction data output circuit 111b and two sets of m registers 12 ₁ a to 12 _m a and 12 ₁ for holding data corresponding to odd / even numbers of the horizontal line. b to 12 _m b), two sets of m D / A converters 13 ₁ a to 13 _m a and 13 ₁ b to 13 _m b connected directly to them, A selector 117 ₁ to 117 _m output to the buffers 14 ₁ to 14 _m to be described later, a selector control circuit 118 for switching control of the selectors 117 ₁ to 117 _m by the horizontal synchronization signal HS, Buffers 14 ₁ to 14 _m . The gamma correction circuit 105c is similar to the gamma correction circuit 105b, for example, a drive method of a line inversion method that inverts the polarity of the positive and negative horizontal lines, and the like. Since the gamma correction setting voltages VI ₁ to VI _m can be changed in accordance with odd / even numbers, the frequency of the horizontal line of the display panel 107 is more preferable.

Patent Document 1: Japanese Patent Application Laid-Open No. 10-108040

Patent Document 2: Japanese Patent Application Laid-Open No. 11-32237

Patent Document 3: US Patent No. 5796384

Patent Document 4: Japanese Patent Application No. 2002-326266 (Japanese Patent Laid-Open No. 2004-165749)

As described above, in the liquid crystal display devices 101, 102, and 103, proper gamma correction is performed by adjusting the gamma correction setting voltages VI ₁ to VI _m in accordance with the individual display panels 107.

However, in recent years, color liquid crystal display devices have become widespread, and larger screens and higher quality of displays have been demanded. In the display panel of the color liquid crystal display device, as shown in Fig. 9 (a), a plurality of display elements are arranged in two dimensions for each color of RGB, and R color (red) and G color (green) in the column direction. ) And B colors (blue) are arranged in a stripe shape. The same figure (b) is a circuit diagram corresponding to the arrangement diagram of (a). The display elements of one row are connected to one gate line Gi (or Gi ₊₁ or the like) and are provided in the order of R color, G color, and B color. The display elements of one column are connected to one source line Sj (or Sj _{+ 1,} etc.) and consist of one color in RGB.

In order to display a good image, it is necessary to balance luminance (i.e., color balance) with respect to each color of RGB and not shift it to a specific color. However, when manufacturing the display panel, if the color balance is broken due to a characteristic difference such as a backlight or a color filter, a phenomenon such as a slight shift to a specific color and, for example, bluish the entire image occurs. The inventor of the present invention also considers the progress of the large screen of the display, and further considers a means for relatively simply adjusting the color balance of the display panel which suppresses the above-described phenomenon in order to further improve the image quality, and the gamma correction circuit. Attention was paid to improving the display panel.

SUMMARY OF THE INVENTION The present invention has been made in view of the above reasons, and an object thereof is to provide a gamma correction circuit, a display panel, and a display device including the same, capable of adjusting the color balance of the display panel.

A gamma correction circuit according to a preferred embodiment of the present invention is a gamma correction circuit that outputs a gamma correction setting voltage for correcting an image voltage according to a nonlinear correlation between an applied voltage of a display element and luminance, and applies to each color of RGB. A gamma correction data output circuit for outputting a plurality of gamma correction data, a plurality of registers for inputting and holding a plurality of gamma correction data, and converting data of the plurality of registers into analog voltages to output gamma correction setting voltages, respectively. A plurality of D / A converters is provided.

The gamma correction data output circuit of this gamma correction circuit preferably outputs a plurality of gamma correction data input from the outside for each color of RGB at the time of gamma correction setting voltage adjustment, and after the gamma correction setting voltage adjustment, For each color, a plurality of gamma correction data are extracted from the nonvolatile memory and output.

Preferably, the gamma correction data output circuit of this gamma correction circuit outputs a plurality of gamma correction data for each color of RGB in order by the horizontal synchronizing signal of the display panel. Alternatively, the plurality of registers of the gamma correction circuit are provided for each color of RGB, and data of the plurality of registers of each color are sequentially inputted to the D / A converter by horizontal synchronization signals of the display panel. do. Or preferably the plurality of registers and the plurality of D / A converters of the gamma correction circuit are provided for respective colors of RGB, and gamma correction setting voltages of the respective colors are sequentially selected by a manual synchronization signal of the display panel. Is output.

In a display panel according to another preferred embodiment of the present invention, a display in which a plurality of display elements are arranged in two dimensions for each color of RGB, and a voltage applied to a source line is applied to a plurality of display elements connected to a selected gate line. As the panel, a plurality of display elements made of one color are connected to each gate line, and a gate line to which a plurality of display elements of each color are connected in turn is selected by a horizontal synchronization signal.

A display device according to still another preferred embodiment of the present invention is provided by inputting the above-described gamma correction circuit and image data according to a preferred embodiment of the present invention, and selecting a gamma correction setting voltage or their interpolation voltage corresponding thereto. And a display panel as described above according to another preferred embodiment of the present invention in which a gate line is driven by a gate driver and a corrected image voltage of the source driver is input to the source line. .

1 is a circuit diagram of a display device according to a preferred embodiment of the present invention.

Fig. 2 shows the same display panel as above, wherein (a) is an arrangement diagram of RGB display elements, and (b) is a circuit diagram corresponding thereto.

3 is a circuit diagram of a display device according to another preferred embodiment of the present invention.

4 is a circuit diagram of a display device according to still another preferred embodiment of the present invention.

5 illustrates general gamma characteristics.

6 is a circuit diagram of a display device of the background art.

7 is a circuit diagram of another display device of the background art.

8 is a circuit diagram of another display device of the background art.

Fig. 9 shows a display panel of color of the background art, (a) is an arrangement diagram of RGB display elements, and (b) is a circuit diagram corresponding thereto.

<Description of the code>

1, 2, 3 liquid crystal display (display device)

5a, 5b, 5c gamma correction circuit

6 source driver

7 display panel

8 gate driver

9 Nonvolatile Memory

11a, 11b gamma correction data output circuit

12 Registers in the ₁ to 12 _m gamma correction circuit 5a

R of the color register in a 12 to 12 ₁ R _m R gamma correction circuit (5b, 5c)

12 G registers in the ₁ G to 12 _m G gamma correction circuits 5b and 5c

12 ₁ B to 12 _m B-color registers in the gamma correction circuits 5b and 5c

13 D / A converter in ₁ to 13 _m gamma correction circuits 5a and 5b

13 ₁ to 13 _m R R D / R A of the color of the gamma correction circuit (5c) converter

13 ₁ G to about 13 G _m D / A of the G color in the gamma correction circuit (5c) converter

B-color D / A converter in 13 ₁ B to 13 _m B gamma correction circuit 5c

EMBODIMENT OF THE INVENTION Hereinafter, preferred embodiment of this invention is described with reference to drawings. 1 is a circuit diagram of a liquid crystal display device 1 according to a preferred embodiment of the present invention. This liquid crystal display device 1 is a gamma correction circuit for outputting gamma correction setting voltages VI ₁ to VI _m for correcting an image voltage according to a nonlinear correlation between an applied voltage of a display element of a liquid crystal and luminance. 5a) and n-bit (for example, 8-bit) image data Di are inputted, and the corrected image voltage Vo is applied by selecting gamma correction setting voltages VI ₁ to VI _m or their interpolation voltages corresponding thereto. A source driver 6 outputted to the display panel 7 to be described later as a voltage for each source line, a display panel 7 having a display element of color liquid crystal, and a gate driver for driving the gate line of the display panel 7. (8) and a nonvolatile memory 9 for storing gamma correction data. Here, the source driver 6 and the gate driver 8 have substantially the same circuit configuration as the liquid crystal display device 101 described above.

The gamma correction circuit 5a inputs gamma correction data of serial inputs sequentially for each color of RGB via an input terminal SD from the outside, and L bits which are digital data corresponding to gamma correction setting voltages VI ₁ to VI _m (eg, For example, a gamma correction data output circuit 11a for converting and outputting 10-bit parallel gamma correction data and m registers (for example, 9) for inputting and holding the parallel gamma correction data (12 ₁ to 12 _m ), and the data output from the registers 12 ₁ to 12 _m , for example, converts to analog voltage, for example, a 10-bit D / A converter (DAC) 13 ₁ to 13 _m , And a buffer 14 ₁ to 14 _m which inputs an analog voltage to be output with the D / A converter (DAC) 13 ₁ to 13 _m and outputs a gamma correction set voltage VI ₁ to VI _m by increasing the current capability. . In addition, when the gamma correction data output circuit 11a adjusts the gamma correction setting voltages VI ₁ to VI _m , the gamma correction data of the serial is input from the external serial gamma correction data sequentially inputted for each color of RGB through the input terminal SD. While converting the correction data into the registers 12 ₁ to 12 _m , the gamma correction data (i.e., the R gamma correction data, the G gamma correction data, and the B gamma correction data) for each color of RGB is stored in a nonvolatile memory ( 9) to preserve. Then, after the gamma correction data output circuit 11a adjusts the gamma correction setting voltages VI ₁ to VI _m , the non-volatile memory for each color of RGB is sequentially turned on by the horizontal synchronization signal HS of the display panel 7. The gamma correction data stored in (9) is taken out and output to the registers 12 ₁ to 12 _m .

As shown in Fig. 2A, a plurality of display elements are arranged in two dimensions for each color of RGB, and the display panel 7 is arranged in a stripe shape in the order of R color, G color, and B color in the row direction. have. The same figure b is a circuit diagram corresponding to the arrangement diagram of a. Each row, that is, each gate line Gi (or Gi _+1, etc.), is connected with a plurality of display elements made of one color of RGB. A plurality of display elements are connected to one column, that is, one source line Sj (or Sj _{+ 1} or the like) in the order of R, G, and B. In the display panel 7, a gate line Gi (or Gi _+1, etc.) to which a plurality of display elements of each color are connected in sequence by the horizontal synchronizing signal HS is selected by the gate driver 8, and the selected gate line is selected. The applied voltage of the source line Sj (or Sj ₊₁ or the like) is applied to the plurality of display elements connected to Gi (or Gi ₊₁ or the like).

Next, the operation when and after the adjustment of the gamma correction setting voltages VI ₁ to VI _m will be described. First, a description will be given when adjusting the gamma correction setting voltages VI ₁ to VI _m . For example, when a plurality of R color gamma correction data is input to the gamma correction circuit 5a in synchronization with the horizontal synchronizing signal HS, the gamma correction setting voltages VI ₁ to VI _m of the R color corresponding to the gamma correction data are reduced. Is output. The R color image voltage Vo corrected by the gamma correction setting voltages VI ₁ to VI _m is output from the source driver 6 to the display panel 7 as an applied voltage. It is important here that the gate line to which the display element of R color is connected in the display panel 7 is selected. That is, the R color image voltage corrected by the R color gamma correction setting voltages VI ₁ to VI _m corresponding to the R color gamma correction data input to the gamma correction circuit 5a is applied to the R color display element. . Then, a plurality of G color gamma correction data is input to the gamma correction circuit 5a in synchronization with the next horizontal synchronizing signal HS, and G is corrected by the gamma correction setting voltages VI ₁ to VI _m of the corresponding G color. An image voltage of color is applied to the display element of G color. The same operation is performed also for B colors, and these operations are repeated for each color of RGB. As described above, gamma correction is performed for each color of RGB, and the display of the display panel 7 is captured in real time, the gamma correction data value from the outside is changed, and the gamma correction setting voltages VI ₁ to VI _m are changed. Adjustments are made to be appropriate.

When the adjustment is completed, the gamma correction data in the adjustment completed state is stored in the nonvolatile memory 9, and after that, the gamma correction data stored in the nonvolatile memory 9 is used. Here, the gamma correction data stored in the nonvolatile memory 9 corresponds to the gamma characteristic for each color of RGB. In addition, the preservation of the gamma correction data in the nonvolatile memory 9 may be performed not only at the completion of the adjustment but also every time new gamma correction data is input from the outside.

After adjusting the gamma correction setting voltages VI ₁ to VI _m for each color of RGB, the gamma correction data stored in the nonvolatile memory 9 is used. In this case, the gamma correction stored in the nonvolatile memory 9 is used. Data extraction is performed for each color of RGB in order by the horizontal synchronizing signal HS. For example, when gamma correction data of R color is taken out by receiving the horizontal synchronizing signal HS, the data is output to the registers 12 ₁ to 12 _m , and the D / A converters 13 ₁ to 13 _m are used. It is converted to an analog voltage and output as the gamma correction setting voltage VI ₁ to VI _m of R color through the buffers 14 ₁ to 14 _m . The image color Vo of the R color corrected by the gamma correction setting voltages VI ₁ to VI _m is output from the source driver 6 to the display panel 7 as an applied voltage, and at this time, as in the above adjustment, the display panel In (7), the gate line to which the display element of R color is connected is selected. The same operation is performed for the G color and the B color, and these operations are repeated for each color of RGB. That is, with the horizontal synchronizing signal HS, the gamma correction circuit 5a sequentially outputs gamma correction setting voltages VI ₁ to VI _m for each color of RGB, and the display panel 7 is connected to display elements of that color. Gate line is selected. As described above, gamma correction is appropriately performed for each color of RGB.

In this manner, the gamma correction circuit 5a can perform gamma correction for each color of RGB, thereby adjusting the color balance of the display panel. In the display panel 7, a plurality of display elements of one color are connected to each gate line, and the gate lines to which a plurality of display elements of each color are sequentially connected are selected by the horizontal synchronization signal HS. By gamma correction by the gamma correction circuit 5a for each color of RGB, the color balance can be adjusted. The liquid crystal display device 1 including the gamma correction circuit 5a and the display panel 7 can display a good image without shifting to a specific color.

Next, the liquid crystal display device 2 which is another preferable embodiment of this invention is demonstrated based on FIG. This liquid crystal display device 2 is an improvement of the liquid crystal display device 1 described above from the viewpoint of suppressing current consumption. The liquid crystal display device 2 includes a source driver 6, a display panel 7, a gate driver 8, and a nonvolatile memory 9 having substantially the same circuit configuration or structure as the liquid crystal display device 1. And a gamma correction circuit 5b having a different configuration from that of the gamma correction circuit 5a. The gamma correction circuit 5b includes a gamma correction data output circuit 11b and three sets of m registers 12 ₁ R to 12 _m R, 12 ₁ G to 12 _m G, 12 _{1 provided} for each color of RGB. B to 12 _m B), selectors 17 ₁ to 17 _m to convert one of the selected sets and output them to the D / A converters 13 ₁ to 13 _m described later, and the horizontal synchronization signal HS in order. And a selector control circuit 18 for switching control of the selectors 17 ₁ to 17 _m , a D / A converter 13 ₁ to 13 _m , and a buffer 14 ₁ to 14 _m .

The gamma correction circuit 5b extracts all gamma correction data from the nonvolatile memory 9 for each color of RGB at the time of power-up, and sets them into three sets of registers 12 ₁ R to 12 _m R, 12 _1. G to 12 _m G, 12 ₁ B to 12 _m B). The data held for each color of this RGB are sequentially selected by the horizontal synchronizing signal HS, input to the D / A converters 13 ₁ to 13 _m , converted into analog voltages, and buffers 14 ₁ to 14 _m . Are output as gamma correction setting voltages VI ₁ to VI _m . As described above, in the liquid crystal display device 1, in the liquid crystal display device 1, extraction of gamma correction data held in the nonvolatile memory 9, i.e., access to the nonvolatile memory 9 is performed for each horizontal synchronization signal HS. On the other hand, access to the nonvolatile memory 9 is made only at the time of power supply, and the number of times thereof is greatly reduced, so that the current consumption can be suppressed.

Next, the liquid crystal display device 3 which is another preferable embodiment of this invention is demonstrated based on FIG. The liquid crystal display device 3 has a source driver 6, a display panel 7, a gate driver 8, and a nonvolatile memory having substantially the same circuit configuration or the same structure as the liquid crystal display devices 1 and 2 described above. (9), and instead of the gamma correction circuits 5a and 5b, a gamma correction circuit 5c different in configuration from them is included. The gamma correction circuit 5c includes a gamma correction data output circuit 11b and three sets of m registers 12 ₁ R to 12 _m R, 12 ₁ G to 12 _m G, 12 _{1 provided} for each color of RGB. B to 12 _m B), three sets of m D / A converters (13 ₁ R to 13 _m R, 13 ₁ G to 13 _m G, 13 ₁ B to 13 _m B) directly connected thereto, selection switch of any one set of selectors (17 ₁ to 17 _m) to be output to the buffer (14 ₁ to 14 _m), which will be described later, and the switching control of the turn, the selector (17 ₁ to 17 _m) by a horizontal synchronizing signal HS And a selector control circuit 18 and buffers 14 ₁ to 14 _m .

The gamma correction circuit 5c extracts all gamma correction data from the nonvolatile memory 9 for each color of RGB at the time of power-up, and sets them into three sets of registers 12 ₁ R to 12 _m R, 12 _1. G to 12 _m G, 12 ₁ B to 12 _m B) and RGB by D / A converter (13 ₁ R to 13 _m R, 13 ₁ G to 13 _m G, 13 ₁ B to 13 _m B) Convert to analog voltage for each color of. The analog voltages for each color of this RGB are sequentially selected by the horizontal synchronizing signal HS, input into the buffers 14 ₁ to 14 _m , and output as gamma correction setting voltages VI ₁ to VI _m . Therefore, this gamma correction circuit 5c suppresses the current consumption of the liquid crystal display device 3 and can convert the gamma correction setting voltages VI ₁ to VI _m at high speed since it is already converted to an analog voltage. Therefore, it is preferable that the frequency of the horizontal line of the display panel 7 is high and high speed processing is required.

In the above gamma correction circuits 5a, 5b, and 5c, if the current output capability of the D / A converter DAC is sufficient, it is also possible to omit the buffers 14 ₁ to 14 _m .

In addition, this invention is not limited to embodiment mentioned above, Various design changes within the range of matter described in a claim are possible. For example, although the liquid crystal display device has been described in the present embodiment, the gamma correction circuit, the display panel, and the display device of the present invention are not limited thereto, and the display device (for example, an organic EL display device) that requires gamma correction is required. It is possible to apply.

According to a preferred embodiment of the present invention, since the gamma correction circuit is provided with a gamma correction data output circuit for outputting a plurality of gamma correction data for each color of RGB, a plurality of display elements of one color are connected to the gate line. By being used together with the displayed display panel, gamma correction can be performed for each color of RGB. As a result, the color balance of the display panel can be adjusted. In addition, the display panel has a plurality of display elements of one color connected to each gate line, and a gate line to which a plurality of display elements of each color are connected in turn is selected by a horizontal synchronization signal. By gamma correction for each color of RGB, color balance can be adjusted. The display device including these gamma correction circuits and the display panel can display a good image without shifting to a specific color.

Claims (11)

A gamma correction circuit for outputting a gamma correction setting voltage for correcting an image voltage according to a nonlinear correlation between an applied voltage of a display element and luminance, A gamma correction data output circuit for outputting a plurality of gamma correction data for each color of RGB, A plurality of registers for inputting and holding a plurality of gamma correction data; And a plurality of D / A converters for converting data of a plurality of registers into analog voltages to output gamma correction setting voltages, respectively. The method of claim 1, The gamma correction setting voltage is output through a buffer. The method according to claim 1 or 2, The gamma correction data output circuit outputs a plurality of gamma correction data input from the outside for each color of RGB when the gamma correction setting voltage is adjusted, and a plurality of the gamma correction data for each color of the RGB after the gamma correction setting voltage is adjusted. Gamma correction circuit, characterized in that for extracting and outputting from the nonvolatile memory. The method according to any one of claims 1 to 3, And the gamma correction data output circuit outputs a plurality of gamma correction data for each color of RGB in order by a horizontal synchronizing signal of a display panel. The method according to any one of claims 1 to 3, And the plurality of registers are provided for each color of RGB, and data of a plurality of registers of each color are sequentially inputted to the D / A converter by a horizontal synchronization signal of the display panel. The method according to any one of claims 1 to 3, The plurality of registers and the plurality of D / A converters are provided for each color of RGB, and a gamma correction circuit for each color is sequentially selected and output by the horizontal synchronization signal of the display panel. . The method according to claim 5 or 6, And said plurality of registers provided for each color of RGB hold gamma correction data extracted from a nonvolatile memory for each color of RGB when the power is turned on. A display panel in which a plurality of display elements are arranged in two dimensions for each color of RGB, and an applied voltage of a source line is applied to a plurality of display elements connected to a selected gate line. A plurality of display elements of one color are connected to each gate line, and a gate line to which a plurality of display elements of each color are connected in turn is selected by a horizontal synchronization signal. A gamma correction circuit according to any one of claims 1 to 7, A source driver for outputting the corrected image voltage by inputting image data and selecting a gamma correction setting voltage or an interpolation voltage corresponding thereto; A display device according to claim 8, wherein the gate line is driven by the gate driver, and the corrected image voltage of the source driver is input to the source line. The method of claim 9, By the horizontal synchronizing signal, a gamma correction circuit sequentially outputs a gamma correction setting voltage for each color of RGB, The display panel is characterized in that the gate line to which the display element of the color is connected is selected. The method of claim 9 or 10, And the display device is a liquid crystal display device.

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