JP2013019922A - Display device and display method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve the problem of degrading of image quality due to steep change of luminance value of an object area and occurrence of false contour depending on a relation between luminance values of the object area and an area around the object area, when processing the luminance value by dividing a display panel into a plurality of areas.SOLUTION: A display device includes a calculation unit for calculating luminance values of the object area radiated by a light source and each of the areas around the object area on the basis of video signals, a signal correction unit for determining a correction amount for correcting the luminance value of the object area to the luminance value of each of the plurality of constituent areas constituting the object area, and a video image correction unit for correcting the input video signals on the basis of the correction amount of the signal correction unit. The signal correction unit determines the correction amount on the basis of a relation between the luminance value of the object area and the luminance value of each of the areas around the object area.

Description

  The present invention relates to a display device and a display method using a backlight.

  A liquid crystal display device using a liquid crystal display element (liquid crystal panel) as a light modulation element includes an illumination light source on the back surface, and displays an arbitrary image by controlling the transmittance of light emitted from the light source by the liquid crystal panel. Is realized.

For these display devices, the display screen is divided into a plurality of divided areas for the purpose of expanding the dynamic range of display luminance and reducing power consumption, and at least one light source is arranged for each area. Some use a configuration in which the luminance of the light source is controlled for each divided region. In the display device having such a configuration, the luminance of the light source in each divided region is controlled according to the characteristics of the video displayed in the region.
Here, as a method of setting the luminance in each divided area, the display luminance in each divided area is detected and the emission luminance of each light source is divided in order to improve image quality while reducing power consumption. Calculated based on the detected display luminance including the influence of the other light sources not arranged corresponding to the region, and based on the amount of deviation between the emission luminance and the optimum value of the display luminance in each part of the display screen A technique for calculating a correction amount for each pixel of a display unit is known (for example, Patent Document 1).
Furthermore, as a method for setting the brightness in each of the divided areas, the display brightness range of the image display device is expanded to an ideal range, and a plurality of areas are supported for the purpose of ensuring image quality. Luminance distribution calculating means for calculating the luminance distribution of the image signal and determining the brightness of the illumination light for each area, and illumination control for controlling the illumination light for each area of the illuminating means based on the determination of the luminance distribution calculating means A configuration employing the means is known (for example, Patent Document 2).

JP 2007-034251 A JP 2005-258403 A

  In Patent Document 1, the light emission luminance of each light source is calculated based on the display luminance detected including the influence on the region of other light sources that are not arranged corresponding to each divided region. Describes a configuration in which the amount of light from other light sources is calculated as constant.

  Furthermore, the above-mentioned patent document 2 describes a configuration for obtaining a luminance distribution between backlight regions using an approximate function.

  However, when actually considering the influence between the divided areas, when displaying a video signal with high quality, it is not a divided area corresponding to the light source but a smaller unit such as a pixel unit (in the present invention). Is a problem that the high-quality video signal cannot be displayed unless the luminance of each component is specified.

Here, as countermeasures against this, as shown in FIG. 13, the light emission luminance value from each light source is specified, and further, for each of the constituent areas constituting each divided area, the distance from each light source is considered, A configuration in which the luminance value of each component area is set is conceivable.
This will be described more specifically. In FIG. 13, the abscissa indicates the distance between the divided regions, while the ordinate indicates the light emission luminance of each light source. In the divided area A, the luminance value from the light source is set to 200, in the divided area B, the luminance value from the light source is set to 80, and in the divided area C, the luminance value from the light source is set. It is assumed that 40 is set. These numbers are used for ease of explanation, and may actually be other values.
In this case, for each component area between the divided areas A and B, in each component area, the distance from the center of the divided area A and the central area of the divided area B, and the divided areas A and B According to the luminance value, the luminance value of each component area can be set.
However, even when such measures are taken, further problems arise when the video signal is as shown in FIG.
This will be described more specifically. In FIG. 14, as in FIG. 13, the horizontal axis indicates the distance of each divided region, while the vertical axis indicates the emission luminance of each light source. In the divided area A, the luminance value from the light source is set to 200, in the divided area B, the luminance value from the light source is set to 40, and in the divided area C, the luminance value from the light source is set. It is assumed that 80 is set. As in the case of FIG. 13, these numbers are used for ease of explanation, and may actually be other values.

  In this case, when the processing as described above is performed, the constituent areas between the divided areas A and B are determined from the center of the divided area A and the central area of the divided area B in each constituent area. Therefore, the luminance values of the respective constituent areas are set linearly as shown in FIG. Will be.

Similarly, with respect to the constituent areas between the divided areas B and C, the distance between the center of the divided area B and the central area of the divided area C and the luminance of the divided areas B and C in each constituent area. Since the brightness value of each constituent area is set according to the value, the brightness of each constituent area is set linearly as shown in FIG.
When the luminance values of the divided areas A to C are as shown in FIG. 14 and the luminance of each constituent area is set linearly, the distribution of the luminance values is actually distributed in the central area of the divided area B. An area with a large change (sharp break point) is formed. In such a case, as a result of applying the rapidly changing luminance value, the calculated video signal correction amount also changes rapidly. Such a suddenly changing correction amount is applied to a smoothly changing video signal, which may cause a suspicious contour to the video signal, which lowers the quality of the video. Problems arise.

  As described above, in order to solve the conventional problem, the present invention aims to provide a high-definition image regardless of the luminance value between a plurality of divided regions.

In order to solve the above-described problem, in the present invention, a display device configured by a display panel that displays an input video signal and a plurality of light sources that illuminate the display panel from the back, Based on the first area irradiated by the light source and the brightness value of each of the surrounding areas of the first area, the brightness value of the first area calculated by the calculation section is the first area. A signal correction unit that determines a correction amount to be corrected to a luminance value for each of a plurality of constituent areas that constitute the image, and a video correction unit that corrects an input video signal based on the correction amount of the signal correction unit, The unit is a display device that sets a correction amount according to the relationship between the luminance value of the first region and the luminance value of each peripheral region of the first region.
Further, in the present invention, the signal correction unit determines the first area when the luminance value of the first area is lower or higher than any of the luminance values of the peripheral area of the first area. The display device is characterized in that a luminance value of a predetermined configuration region among a plurality of configuration regions is configured to be substantially constant.
Further, in the present invention, the signal correction unit includes a plurality of constituent areas constituting the first area when the luminance value of the first area is an intermediate luminance value of the luminance values of the peripheral area of the first area. Is a display device characterized in that it is an intermediate value of the luminance values of the peripheral region of the first region.

  With this configuration, the signal correction unit can set a plurality of correction amounts according to the relationship between the luminance value of the first region and the luminance value of each peripheral region of the first region. The object is to provide a high-quality image regardless of the luminance value between the divided areas.

The figure which shows the structure of the liquid crystal display device of this invention The figure which shows the structure of the signal correction means of this invention The figure which shows the processing content (keystone correction) of the liquid crystal display device of this invention The figure which shows the processing content (keystone correction) of the liquid crystal display device of this invention The figure which shows the processing content (straight line correction) of the liquid crystal display device of this invention The figure which shows the processing content (straight line correction) of the liquid crystal display device of this invention The figure which shows the processing content (keystone correction) of the liquid crystal display device of this invention The figure which shows the processing content (straight line correction) of the liquid crystal display device of this invention The figure which shows the processing content (keystone correction) of the liquid crystal display device of this invention The figure which shows the division area and component area of this invention The figure which shows the processing content of the liquid crystal display device of this invention The figure which shows the structure of the interpolation means of this invention The figure which shows the processing content of the conventional liquid crystal display device The figure which shows the processing content of the conventional liquid crystal display device

(Embodiment 1)
<1. Overall configuration of liquid crystal display device>
A liquid crystal display device according to the first embodiment of the present invention will be described. FIG. 1 is a block diagram showing the configuration of the liquid crystal display device according to the first embodiment of the present invention. The liquid crystal display device shown in FIG. 1 includes a calculating unit 102, a signal correcting unit 104, a display panel driving unit 106, a display panel 108, a backlight driving unit 110, and a backlight unit 112. Hereinafter, each configuration will be described in detail.
<1-1. Configuration related to display panel>
First, the calculation means 102 will be described. The calculating unit 102 calculates a luminance value from the input video signal and outputs the calculated luminance value to the signal correcting unit 104. The calculation of the luminance value at this time is performed in units of divided areas obtained by dividing the display panel 108 described later into a plurality of areas. The calculation means 102 generates a luminance value from the input video signal based on the peak value and average value of the pixels in each divided region.

  Next, the signal correction unit 104 will be described. The signal correcting unit 104 corrects the luminance value from the luminance value of each divided area calculated by the calculating unit 102, and then sets the transmittance of a liquid crystal layer of the display panel 108 to be described later. The detailed configuration of the signal correction unit 104 will be described in detail with reference to FIG.

Next, the display panel driving unit 106 and the display panel 108 will be described. Although not shown, the display panel 108 includes a plurality of gate lines, a plurality of source lines, a switching element, and a plurality of pixel cells, and a plurality of pixels in a matrix at intersections of the plurality of source lines and the plurality of gate lines. Are arranged, and one scanning line is constituted by one line of pixels in the horizontal direction.
A plurality of source lines are supplied with pixel signals from the display panel driving means 106, and a plurality of gate lines are supplied with gate pulses as scanning signals from the display panel driving means 106, and a signal voltage is applied to the liquid crystal layer corresponding to each pixel. Is given to control the transmittance. Here, in the display panel 108, as indicated by a dotted line in FIG. 1, the display unit is divided into a plurality of divided regions.

In addition to the IPS (In Plane Switching) method, the display panel 108 may be any method such as a VA (Vertical Alignment) method or a UV2A (Ultraviolet induced multi-domain Vertical Alignment) method that irradiates liquid crystal molecules with ultraviolet rays. Is applicable.
<1-2. Configuration related to backlight unit>
The backlight unit 112 has a function of irradiating illumination light for displaying an image on the display panel 108 from the back side. The backlight unit 112 is divided into a plurality of regions, like the display panel 108.
Each divided area illuminates a divided area at the same position on the display panel 108. Each divided area has at least one light source. As the light source, a white LED or an RGB LED that obtains white light using RGB three-color LEDs is used.
The LEDs belonging to each divided area are driven by the backlight driving means 110. The luminance for each region is independently driven by the backlight driving unit 110 based on the luminance value calculated by the calculating unit 102. Although not shown, each divided area is connected to the backlight driving means 110 by a control line.
Although not shown in FIG. 1, a configuration is adopted in which light emitted from the LEDs of the backlight unit 112 is made uniform by providing a diffusion sheet between the display panel 108 and the backlight unit 112. It is also possible to do.
<1-3. Configuration of Signal Correction Unit>
As shown in FIG. 2, the signal correction unit 104 is connected to the calculation unit 102 and the video correction unit 160, and includes a comparison unit 150, a straight line correction unit 152, a trapezoid correction unit 154, a selection unit 156, and a correction unit. 158.

  In the signal correction means 104, the luminance value of each divided area is calculated by the calculation means 102 described above, and the luminance value for each divided area is input.

  Next, the comparison unit 150 compares the luminance value of one divided area calculated by the calculation unit 102 with the luminance values of the divided areas around the divided area. Note that the luminance value calculated by the calculating means 102 is set such that the LED is in a non-luminous luminance state 0 and the maximum light emitting state is 255. In the present embodiment, for simplicity of explanation. The luminance values emitted from the LEDs arranged in each divided area are shown, but the present invention is not limited to this, and for example, the luminance values emitted from the LEDs arranged in each divided area In addition, it is possible to set a value that takes into account the influence of light emission from the LEDs arranged in other divided regions as the luminance value. This point will be described in detail in a second embodiment to be described later.

Next, a specific example will be described with reference to FIGS. As shown in FIG. 3, the A region includes A (1,1), A (1,2), A (1,3), A (2,1), A (2,2), A (2, 3) An example in which nine pixels of A (3, 1), A (3, 2), and A (3, 3) are emitted by one LED. Similarly, the B region includes B (1, 1), B (1, 2), B (1, 3), B (2, 1), B (2, 2), B (2, 3). , B (3,1), B (3,2), and B (3,3) emit light from one LED, and the regions are C (1,1), C (1 , 2), C (1, 3), C (2, 1), C (2, 2), C (2, 3), C (3, 1), C (3, 2), C (3, The nine pixels of 3) are emitted by one LED.
As shown in the lower diagram of FIG. 3, the luminance value of the A region is 200, the luminance value of the B region is 40, and the luminance value of the C region is 80. Here, assuming that the target area is B, the target area B has lower luminance than any luminance value of the peripheral area. In this embodiment, for simplification of explanation, only the horizontal direction is compared. However, the present invention is not limited to this, and only the vertical method, the vertical direction and the horizontal direction are compared. It is also possible to employ a configuration that compares both regions.
Further, as shown in the lower diagram of FIG. 4, the luminance value of the A region is 40, the luminance value of the B region is 200, and the luminance value of the C region is 80. Here, assuming that the target area is B, the target area B has higher brightness than any brightness value of the peripheral area. In this embodiment, for simplification of explanation, only the horizontal direction is compared. However, the present invention is not limited to this, and only the vertical method, the vertical direction and the horizontal direction are compared. It is also possible to employ a configuration that compares both regions.

  On the other hand, in FIG. 5, as in FIG. 3, the A region includes A (1,1), A (1,2), A (1,3), A (2,1), A (2,2). , A (2,3), A (3,1), A (3,2), and A (3,3), an example in which one pixel emits light. Similarly, the B region includes B (1, 1), B (1, 2), B (1, 3), B (2, 1), B (2, 2), B (2, 3). , B (3,1), B (3,2), and B (3,3) emit light from one LED, and the regions are C (1,1), C (1 , 2), C (1, 3), C (2, 1), C (2, 2), C (2, 3), C (3, 1), C (3, 2), C (3, The nine pixels of 3) are emitted by one LED.

  As shown in the lower diagram of FIG. 5, the luminance value of the A region is 200, the luminance value of the B region is 80, and the luminance value of the C region is 40. Here, assuming that the target area is B, the target area B has a lower luminance than the target area A, but has a higher luminance than the target area C, and becomes an intermediate luminance value of the luminance values of the peripheral area. Yes. In this embodiment, for simplification of explanation, only the horizontal direction is compared. However, the present invention is not limited to this, and only the vertical method, the vertical direction and the horizontal direction are compared. It is also possible to employ a configuration that compares both regions.

  Further, as shown in FIG. 6, the brightness value of the A area is 40, the brightness value of the B area is 80, and the brightness value of the C area is 200. Here, if the target area is B, the target area B has a lower luminance than the target area C, but has a higher luminance than the target area A, and is an intermediate luminance value of the luminance values of the surrounding areas. Yes. In this embodiment, for simplification of explanation, only the horizontal direction is compared. However, the present invention is not limited to this, and only the vertical method, the vertical direction and the horizontal direction are compared. It is also possible to employ a configuration that compares both regions.

  As described above, the comparison unit compares the luminance value of one divided area calculated by the calculating unit 102 with the luminance value of the divided areas around the divided area, and the target divided area is any of the peripheral areas. The luminance value is lower or higher than the luminance value (in the case of FIGS. 3 and 4), or the target divided region is an intermediate luminance value (in the case of FIGS. 5 and 6) of the luminance values of the peripheral region. Is determined.

  Next, the straight line correction unit 152 and the trapezoidal correction unit 154 will be described with reference to FIGS. FIG. 7 shows the processing of the straight line correction unit 152 and the trapezoidal correction unit 154 for the cases of FIGS. 3 and 4 described above. The solid line indicates the luminance value corrected by the trapezoid correcting unit 154, while the dotted line indicates the luminance value corrected by the straight line correcting unit 152. On the other hand, FIG. 8 shows the processing of the straight line correction means 152 and the trapezoid correction means 154 for the cases of FIGS. 5 and 6 described above. A solid line indicates the luminance value corrected by the straight line correction unit 152, while a dotted line indicates the luminance value corrected by the trapezoid correction unit 154.

  As can be seen from FIG. 7, when the target divided area is lower or higher in luminance than any of the luminance values of the surrounding areas, the trapezoid correcting means 152 has a plurality of parts constituting the target divided area B. Among the constituent areas, the luminance value of the predetermined constituent area is a substantially constant value, and in the central area of the divided area B, an area having a large change in the luminance value distribution (sharp break point) is formed. It becomes possible to solve the problem that the false contour is generated and the quality of the image is lowered. On the other hand, in the straight line correction unit 152, a region (sharp break point) in which the change of the luminance value distribution is large is formed in the central region of the divided region B, which causes a problem that the quality of the image is lowered.

  Further, as is clear from FIG. 8, when the target divided region is an intermediate luminance value of the luminance values of the peripheral region, the straight line correction unit 152 has a plurality of components constituting the target divided region B. The constituent areas are a distribution of luminance values and linear luminance values of the peripheral area A and the peripheral area B. On the other hand, in the trapezoidal correction means 152, the luminance value of a predetermined constituent area among the plurality of constituent areas constituting the target divided area B is a substantially constant value, and the luminance of this part is uniform. Therefore, there is a problem that the image becomes a flat image and the quality of the image is lowered.

  Therefore, in the present invention, the comparison unit 150 causes the selection unit 156 to select either the straight line correction unit 152 or the trapezoidal correction unit 154 according to the relationship between the luminance value of the target divided region and the luminance value of the surrounding region. By selecting, it becomes possible to select an appropriate correction method.

  Specifically, when the target divided area is lower or higher in luminance than any of the brightness values of the surrounding areas, the trapezoid correcting unit 152 is selected to form a plurality of areas constituting the target divided area B. Among the constituent areas, the luminance value of the predetermined constituent area becomes a substantially constant value, and in the central area of the divided area B, an area having a large change in the luminance value distribution (sharp break points) is generated, so that a false contour is generated. Thus, it is possible to solve the problem that the quality of the image is lowered. On the other hand, when the target divided area is an intermediate luminance value of the luminance values of the peripheral area, by selecting the straight line correction unit 152, a plurality of constituent areas constituting the target divided area B are changed to the peripheral area A and It becomes possible to set a luminance value that is linear with a luminance value with respect to the peripheral region B, and it is possible to provide an image without a sense of incongruity.

  Next, the video correction unit 160 corrects the video signal based on the luminance value corrected by either the straight line correction unit 152 or the trapezoidal correction unit 154 selected by the selection unit 156, and the corrected video is displayed. The transmittance of the display panel 108 is set based on the signal.

  With the above configuration, by setting the correction amount according to the relationship between the luminance value of the target divided region and the luminance value of each peripheral region of the target divided region, what luminance value is between the plurality of divided regions Even in this case, it is possible to provide high-quality video.

  Note that the trapezoidal correction unit 152 changes the slope of the luminance value with respect to the input video signal as shown in FIG. 9 in addition to the method in which the luminance value of the predetermined configuration area is substantially constant. By doing so, it can also be realized. In this case, although not shown, an inclination correction unit is provided in the trapezoid correction unit 152, and the luminance value of the predetermined constituent area described above is corrected by correcting the angle of the luminance value calculated by the calculation unit 102. Can be set to a substantially constant value.

That is, in the inclination correction unit, the luminance value of the target region is compared with the luminance value of the target region as compared with the intermediate luminance value of the luminance values of the peripheral region of the target region. When the brightness value is lower or higher than any brightness value in the surrounding area, the amount of change in the brightness value of the target area is set gently. Note that the above-described configuration area is formed by one pixel unit. It may be composed of a plurality of pixels.
(Embodiment 2)
In the present invention, the following contents can be added in addition to the first embodiment described above. In the first embodiment, it has been described on the assumption that the luminance value of each divided area itself is constant in a plurality of constituent areas constituting each divided area.
However, in practice, in a plurality of constituent areas constituting the divided area, for example, in a constituent area located near the boundary between the constituent area located at the center of the divided area and the other divided areas, The closer to the boundary, the more easily affected by the light emitted in other divided areas. For example, as illustrated in FIG. 10, the configuration areas a, b, c, d, f, g, h, and i are all in contact with other division areas, and the configuration areas e that are not in contact with other division areas. The effect of light from other divided areas is different.
Therefore, in the present invention, as shown in FIG. 11, the divided regions are configured by correcting the luminance value set for each divided region according to the position of each pixel from the center of the plurality of divided regions. It is possible to set a luminance value according to the position of the configuration area. In other words, the luminance value of each component region can be changed according to the luminance distribution from the light source arranged in the target divided region and the luminance distribution from the light source arranged in the peripheral region around the target divided region. It will be possible.
As a specific configuration, as shown in FIG. 12, the interpolation means 202 inputs the luminance values of the light sources of the divided areas 1 and 2 and the horizontal coordinate value x, and the point A in FIG. Interpolates luminance values. Similarly, the interpolation unit 204 inputs the luminance values of the light sources in the divided areas 3 and 4 and the horizontal coordinate value x, and interpolates the luminance values at the point B in FIG. Further, the interpolation unit 206 inputs the luminance value at the point A, the luminance value at the point B, and y which is the coordinate value in the vertical direction, and interpolates the luminance value of the estimation target pixel in FIG.
With such a configuration, it is possible to correct the brightness value according to the brightness distribution regardless of the position of the plurality of constituent areas constituting the divided area, thereby providing a higher quality image. It is possible to do that.

  In a display device configured by a display panel that displays an input video signal and a plurality of light sources that irradiate the display panel from the back, it is useful as a display device and a display method that can display high-quality video.

DESCRIPTION OF SYMBOLS 102 Calculation means 104 Signal correction means 106 Panel drive means 108 Display panel 110 Backlight drive means 112 Backlight unit 150 Comparison means 152 Linear correction means 154 Trapezoid correction means 156 Selection means 160 Video correction means 202 Interpolation means 204 Interpolation means 206 Interpolation means

Claims (14)

A display device configured by a display panel that displays an input video signal and a plurality of light sources that irradiate the display panel from the back,
A calculation unit that calculates a luminance value of each of the first region irradiated by the light source and each peripheral region based on the video signal; and
A signal correction unit for determining a correction amount for correcting the luminance value of the first region calculated by the calculation unit to a luminance value for each of a plurality of constituent regions constituting the first region;
A video correction unit that corrects an input video signal based on a correction amount of the signal correction unit;
The display device, wherein the signal correction unit sets the correction amount according to a relationship between a luminance value of the first region and a luminance value of each peripheral region of the first region. The signal correction unit includes a plurality of components constituting the first region when the luminance value of the first region is lower or higher than any luminance value of the peripheral region of the first region. The display device according to claim 1, wherein a luminance value of a predetermined configuration area among the configuration areas is substantially constant. When the luminance value of the first region is an intermediate luminance value of the luminance values of the peripheral region of the first region, the signal correction unit includes a plurality of constituent regions constituting the first region, The display device according to claim 1, wherein the display device is an intermediate value of luminance values of a peripheral region of the first region. The signal correction unit is configured such that the luminance value of the first region is higher than the luminance value of the first region as compared with the case where the luminance value of the first region is an intermediate luminance value of the peripheral region of the first region. An inclination correction unit that gently sets a change amount of the luminance value of the first region when the luminance value is lower or higher than any luminance value of the peripheral region of the region. The display device according to any one of 1 to 3. The said signal correction part correct | amends a luminance value according to the luminance value distribution from the light source arrange | positioned in the said 1st area | region about the some structure area which comprises the said 1st area | region. The display device according to 1 to 4. The signal correction unit includes, for a plurality of constituent regions constituting the first region, luminance value distributions from light sources disposed in the first region and light sources disposed in a peripheral region of the first region. 5. The display device according to claim 1, wherein the luminance value is corrected in accordance with the luminance distribution. The display device according to claim 1, wherein the plurality of constituent regions constituting the first region are configured by a plurality of pixels or pixel units. A display method that includes a display panel that displays an input video signal and a plurality of light sources that illuminate the display panel from the back,
A calculation step for calculating a luminance value of each of the first region irradiated by the light source and each peripheral region of the first region based on the video signal;
A signal correction step for determining a correction amount for correcting the luminance value of the first region calculated in the calculation step to a luminance value for each of a plurality of constituent regions constituting the first region;
A video correction step of correcting the input video signal based on the correction amount of the signal correction step,
The display method according to claim 1, wherein the signal correction step sets the correction amount according to a relationship between a luminance value of the first area and a luminance value of each peripheral area of the first area. In the signal correction step, when the luminance value of the first area is lower or higher than any of the luminance values in the peripheral area of the first area, a plurality of the first area are configured. The display method according to claim 8, wherein a luminance value of a predetermined configuration area among the configuration areas is substantially constant. In the signal correction step, when the luminance value of the first area is an intermediate luminance value of the luminance values of the peripheral area of the first area, a plurality of constituent areas constituting the first area are The display method according to claim 8, wherein the display method is an intermediate value of luminance values in a peripheral area of the first area. In the signal correction step, the luminance value of the first region is set to the first luminance value as compared with the case where the luminance value of the first region is an intermediate luminance value of the luminance values of the peripheral region of the first region. The slope correction step of gently setting a change amount of the brightness value of the first area when the brightness value is lower or higher than any brightness value of the peripheral area of the area. The display method according to any one of 8 to 10. The said signal correction step correct | amends a luminance value according to the luminance value distribution from the light source arrange | positioned in the said 1st area | region about the some structure area which comprises the said 1st area | region. The display method according to 8 to 11. In the signal correction step, for a plurality of constituent areas constituting the first area, a luminance value distribution from a light source arranged in the first area and a light source arranged in a peripheral area of the first area The display device according to claim 8, wherein the luminance value is corrected in accordance with the luminance distribution. 14. The display device according to claim 8, wherein the plurality of constituent regions constituting the first region are configured by a plurality of pixels or pixel units.

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