JP2017076064A - Display device and control method and program for the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a display device capable of displaying an image while maintaining good gradation even when a gradation value of an image to be displayed on a liquid crystal panel on an illumination device side is varied by a gradation conversion process.SOLUTION: Display means 100 of the present invention includes: a generation part 140 for generating a display image A by processing a pixel in a predetermined region that belongs to a region 182 having a low gradation value than in a region 181 of an input image 180 and adjoining to the region 181, and that is close to the region 181, to increase a gradation value; a generation part 150 for generating a display image B by converting a gradation value of the input image 180 by using the gradation value of the display image A; a backlight 130 for projecting light; a liquid crystal panel 121 for modulating the light projected from the backlight 130 on the basis of the display image A; and a liquid crystal panel 120 for further modulating the light modulated by the liquid crystal panel 121 on the basis of the display image B.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a display device including a transmissive display panel, a control method for the display device, and a program.

  As a technique for improving the contrast of a display device using a transmissive liquid crystal panel, there is a technique in which two liquid crystal panels are arranged in an overlapping manner on a lighting device. Japanese Patent Application Laid-Open No. 2004-133867 discloses a technique for suppressing luminance fluctuations of pixels depending on the line-of-sight direction by performing a smoothing process for increasing the gradation of a partial area of an image displayed on a liquid crystal panel arranged on the lighting device side. It is disclosed.

JP 2008-191269 A

  However, in the above-described conventional technology, an image displayed on the display device is different from the input image when viewed from the front by performing a smoothing process on the image displayed on the liquid crystal panel on the lighting device side. May appear.

  Therefore, in view of the above problems, the present invention maintains an excellent gradation even when the gradation value of an image displayed on the liquid crystal panel on the lighting device side is changed by the gradation conversion processing. An object is to provide a display device capable of displaying.

  In order to solve the above-described problem, the display device of the present invention is adjacent to the first region in the second region adjacent to the first region of the input image and having a gradation value lower than that of the first region. A first processing means for generating a first image by performing a process for increasing the gradation value of pixels in a predetermined area, and converting the gradation value of the input image using the gradation value of the first image Second processing means for performing processing to generate a second image, illumination means for irradiating light, first modulation means for modulating light emitted from the illumination means based on the first image, And second modulation means for further modulating the light modulated by the first modulation means based on the second image and outputting an image.

  In addition, according to the control method of the display device of the present invention, the pixel level of the region adjacent to the first region in the second region having a lower gradation value than the first region adjacent to the first region of the input image. Corresponding to the pixel using a gradation conversion process for generating a first image by performing a gradation conversion process for increasing the tone value, and the gradation value of the input image and the gradation value of the first image Determining a gradation value of a pixel of the second image to be generated, generating a second image, and a first output for outputting the first image to a first modulation unit that modulates light emitted from the illumination unit And a second output step of outputting the second image to a second modulation unit that further modulates the light modulated by the first modulation unit.

  According to the image processing device of the present invention, when the first image in which the tone value is changed by the tone conversion processing on the input image is displayed on the liquid crystal panel on the lighting device side, the tone of the first image is displayed. The second image in which the gradation value of the input image is changed according to the value is displayed on the liquid crystal panel on the front side.

  Therefore, even when the gradation value of the image displayed on the liquid crystal panel on the lighting device side is changed by the gradation conversion process, it is possible to display an image while maintaining good gradation.

It is a block diagram which shows the functional block of the display apparatus 100 in a 1st Example. It is the schematic which shows the structure of the display apparatus 100 in a 1st Example. 2 is a schematic diagram illustrating a configuration of pixels of liquid crystal panels 120 and 121. FIG. It is the schematic diagram which showed the input image 180 in a 1st Example. FIG. 6 is a schematic diagram illustrating a luminance image generation process in a MaxRGB conversion unit 141. FIG. 6 is a schematic diagram illustrating a display image A generation process in a smoothing processing unit 142. FIG. 5 is an enlarged schematic diagram illustrating a region of a display image B corresponding to a region A of an input image 180 illustrated in FIG. 4. It is a schematic diagram which shows the relationship between the input gradation value and the transmittance | permeability of liquid crystal panel 120,121. It is the schematic diagram which showed the transmittance | permeability of each pixel at the time of displaying an image on liquid crystal panel 120,121 based on description of a 1st Example. It is a block diagram which shows the functional block of the display apparatus 200 in a 2nd Example. It is the schematic diagram which showed the input image 280 in a 2nd Example. It is the schematic diagram which expanded and showed the area | region of the pre-processing image and smoothing image corresponding to the area | region B of the input image 280 shown in FIG. FIG. 12 is a schematic diagram illustrating an enlarged region of a luminance image and an extended image corresponding to a region B of the input image 280 illustrated in FIG. 11. FIG. 12 is a schematic diagram in which a region of a display image A2 corresponding to a region B of an input image 280 illustrated in FIG. 11 is enlarged. It is the schematic diagram which showed the transmittance | permeability of each pixel at the time of displaying an image on liquid crystal panel 220,221 based on description of the 2nd Example. It is a block diagram which shows the functional block of the display apparatus 200 in a 2nd Example.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The technical scope of the present invention is determined by the scope of claims, and is not limited by the examples illustrated below. Further, not all the combinations of features described in the embodiments are essential to the present invention. The contents described in this specification and drawings are illustrative and should not be construed as limiting the present invention. Various modifications (including organic combinations of the embodiments) are possible based on the spirit of the present invention, and they are not excluded from the scope of the present invention.

(First embodiment)
FIG. 1 is a block diagram illustrating functional blocks of the display device 100 according to the first embodiment. The display device 100 includes an image input unit 110, a liquid crystal panel 120, a liquid crystal panel 121, a backlight 130, a generation unit 140, a generation unit 150, a control unit 160, and a memory 170.

  The image input unit 110 outputs an input image to be displayed on the display device 100 to the generation unit 140 and the generation unit 150. The input image is image data in which gradation values of red (Red, R), green (Green, G), and blue (Blue, B) are represented by 8-bit information for each of a plurality of pixels. These are images selected by the user from a plurality of images stored in a storage unit (not shown) inside the display device 100, images input from the outside of the display device 100, and the like.

  The liquid crystal panels 120 and 121 are transmissive display panels having a plurality of liquid crystal elements, each of which can individually control the transmittance. The liquid crystal panels 120 and 121 are modulation devices that spatially modulate incident light.

  FIG. 2 is an exploded perspective view of the display device 100 showing the positions of the liquid crystal panel 120, the liquid crystal panel 121, and the backlight 130 in the first embodiment. A liquid crystal panel 121 is disposed on the front side of the backlight 130. The liquid crystal panel 120 is disposed on the front side of the liquid crystal panel 121. In other words, it can be said that the liquid crystal panel 121 is disposed between the backlight 130 and the liquid crystal panel 120.

  The light emitted from the backlight 130 to the liquid crystal panel 121 is modulated by the liquid crystal panel 121. Further, the light modulated by the liquid crystal panel 121 is further modulated by the liquid crystal panel 120. By modulating the light by the liquid crystal panels 120 and 121, it is possible to reduce the influence of light leakage of the liquid crystal panel even in a dark region of an image.

  FIG. 3A is a schematic diagram illustrating the configuration of the pixels of the liquid crystal panel 120. The liquid crystal panel 120 includes 1920-1080 pixels arranged in a matrix of 1920 pixels in the horizontal direction and 1080 pixels in the vertical direction. The number of pixels included in the liquid crystal panel 120 is not limited to the number described above, and may be m × n (m and n are arbitrary integers). Each pixel of the liquid crystal panel 120 has three subpixels corresponding to R, G, and B, and the light transmittance can be controlled for each subpixel. Each sub-pixel includes a color filter of a corresponding color, and controls the transmittance of light of the corresponding color. The liquid crystal panel 120 controls the light transmittance for each subpixel according to the RGB gradation values of the image input to the liquid crystal panel 120.

  FIG. 3B is a schematic diagram illustrating the configuration of the pixels of the liquid crystal panel 121. Similarly to the liquid crystal panel 120, the liquid crystal panel 121 includes 1920 pixels arranged in a matrix of 1920 × 1080 pixels in the horizontal direction and 1080 pixels in the vertical direction. The number of pixels included in the liquid crystal panel 120 is not limited to the number described above, and may be m × n (m and n are arbitrary integers). The pixels of the liquid crystal panel 121 can control the light transmittance for each pixel. The liquid crystal panel 121 controls the light transmittance for each pixel in accordance with the image input to the liquid crystal panel 121.

  The backlight 130 is a lighting device including a light source that generates light, an optical unit that irradiates the liquid crystal panel 121 with light generated from the light source, a control circuit that controls the light source, and the like. The light source is a Light-Emitting Diode (LED) light source, a laser light source, a fluorescent tube, or the like. The amount of light emitted from the light source is uniformly controlled with respect to the liquid crystal panel 121. Note that the light emission amount of the light source can be individually controlled for each of a plurality of regions of the backlight 130 according to the gradation value of the input image. The light emitted from the backlight 130 to the liquid crystal panel 121 is emitted to the liquid crystal panel 121.

  The generation unit 140 generates a display image A by converting the gradation of the input image, and outputs the display image A to the liquid crystal panel 121 and the generation unit 150. The generation unit 140 includes a MaxRGB conversion unit 141 and a smoothing processing unit 142. The MaxRGB conversion unit 141 sets the largest gradation value among the R, G, and B gradation values of each pixel of the input image as the gradation value of the pixel. The MaxRGB conversion unit 141 converts the input image into a luminance image having one gradation value for each pixel. The MAXRGB conversion unit 141 outputs the luminance image to the smoothing processing unit 142.

  The smoothing processing unit 142 performs a smoothing process on the luminance image. Specifically, first, the gradation value of each pixel of the luminance image is replaced with the largest gradation value of a plurality of pixels included in a 5 × 5 pixel area centered on the pixel, Generate a processed image. Next, the gradation value of each pixel of the preprocessed image is replaced with the average value of the gradation values of a plurality of pixels included in the 5 × 5 pixel area centered on the pixel, and the display image A is generated. The smoothing processing unit 142 outputs the display image A to the generation unit 150 and the liquid crystal panel 121.

  In this embodiment, the reference area is a 5 × 5 pixel area, but the size of the reference area is not limited to this. However, it is desirable that the size of the reference area is the same in the generation of the preprocessed image and the generation of the display image A.

  The generation unit 150 generates a display image B based on the display image A and the input image, and outputs the display image B to the liquid crystal panel 120. Specifically, the R, G, and B gradation values of each pixel of the input image include the gradation value of the pixel of the display image A corresponding to the pixel and the maximum gradation value that the display image A can take. To obtain the gradation value of the pixel of the display image B corresponding to the pixel. Expression 1 is an expression showing the relationship between the gradation value (R0, G0, B0) of a pixel in the input image and the gradation value (R1, G1, B1) of the corresponding pixel of the display image B. Here, K is the gradation value of the pixel of the corresponding display image A. Since the gradation value of the input image is expressed by 8 bits, the maximum value that the pixel of the display image A can take is 255.

  The control unit 160 controls each functional block of the display device 100. In this embodiment, the control unit 160 is a computer. By executing the program stored in the memory 170, the operation of each functional block of the display device 100 is controlled. The control unit 160 is a central processing unit (CPU) or a micro processing unit (MPU). The storage unit is a non-volatile storage medium or the like.

  The memory 170 is a storage medium that stores programs and parameters that can be executed by the control unit 160 to control each functional block. The memory 170 may be of any type such as a nonvolatile storage medium.

  Hereinafter, the operation of the display device 100 according to the first embodiment will be described in detail. FIG. 4 is a schematic diagram showing the input image 180 in the first embodiment. The input image 180 has a region 181 and a region 182. The gradation value of R, G, B of each pixel included in the area 181 is 255, and the gradation value of R, G, B of each pixel included in the area 182 is 20. That is, it can be said that the input image 180 is divided into a region 181 displaying a white image and a region 182 displaying a gray image on the left and right. The input image 180 is output from the image input unit 110 to the generation unit 140 and the generation unit 150.

  FIG. 5 is a schematic diagram illustrating a luminance image generation process in the MaxRGB conversion unit 141. FIG. 5A is a schematic diagram showing the area A of FIG. 4 in an enlarged manner. The area A has 8 × 5 pixels in total, 8 in the horizontal direction and 5 in the vertical direction. The XX straight line in the figure becomes the boundary between the region 181 and the region 182. For each pixel of the input image, a gradation value is set for each of R, G, and B. The MaxRGB conversion unit 141 uses the maximum gradation value among the R, G, and B gradation values of each pixel of the input image to obtain the gradation value of the pixel of the luminance image corresponding to the pixel.

  FIG. 5B is a schematic diagram showing an enlarged region of the luminance image corresponding to the region A of the input image 180 shown in FIG. Each pixel of the luminance image has the maximum gradation value among the R, G, and B gradation values of the corresponding pixel of the input image. The MaxRGB conversion unit 141 outputs the luminance image to the smoothing processing unit 142.

  FIG. 6 is a schematic diagram illustrating a display image A generation process in the smoothing processing unit 142. FIG. 6A is a schematic diagram showing an enlarged region of the preprocessed image corresponding to the region A of the input image 180 shown in FIG. The smoothing processing unit 142 converts the gradation value of each pixel of the luminance image into the maximum gradation value among the gradation values of the pixels included in the reference region of 5 × 5 pixels centering on the pixel, A preprocessed image is generated. As a result of the conversion of the gradation value, as shown in FIG. 6A, the gradation value of the pixel adjacent to the area 181 among the pixels of the area 182 is converted to the gradation value of the pixel of the area 181.

  FIG. 6B is a schematic diagram showing an enlarged region of the display image A corresponding to the region A of the input image 180 shown in FIG. The smoothing processing unit 142 converts the gradation value of each pixel of the preprocessed image into an average value of the gradation values of the pixels included in the reference region of 5 × 5 pixels centered on the pixel, and displays the display image A. Generate.

  As a result of converting the gradation values, as shown in FIG. 6B, the gradation values of the pixels included in the region close to the region 181 among the pixels in the region 182 are increased. In other words, it can be said that the gradation value is converted so that the step of the gradation value between the region 182 and the region 181 changes smoothly and continuously. The smoothing processing unit 142 outputs the generated display image A to the liquid crystal panel 121 and the generating unit 150.

  The generation unit 150 converts the input image using the display image A to generate the display image B. The generation unit 150 generates the display image B by converting the gradation value of each pixel of the input image based on the gradation value of the corresponding pixel of the display image A and Expression 1. FIG. 7 is a schematic diagram showing an enlarged region of the display image B corresponding to the region A of the input image 180 shown in FIG. The generation unit 150 multiplies the gradation value of each pixel of the input image by the ratio of the gradation value of the pixel of the corresponding display image A and the maximum gradation value that the display image A can take, and displays the display image. The gradation value of each pixel of B is determined. The generation unit 150 outputs the display image B to the liquid crystal panel 120.

  Based on the display image B, the liquid crystal panel 120 controls the transmittance of subpixels corresponding to R, G, and B of each pixel of the liquid crystal panel 120. The liquid crystal panel 121 controls the transmittance of each pixel of the liquid crystal panel 121 based on the display image A. FIG. 8 is a schematic diagram showing the relationship between the input gradation value and the transmittance of each sub-pixel of the liquid crystal panels 120 and 121. The transmittance is described as a ratio to the transmittance at the maximum value (255) of the input gradation value. The transmittance becomes T0 when the input gradation value is 0, and increases linearly as the input gradation value increases. T0 is a value determined by the characteristics of the liquid crystal panel. In the first embodiment, T0 is 0.05. Therefore, the relationship between the input gradation value and the transmittance is (transmittance) = 255 / (1-0.05) × (gradation value) +0.05.

  FIG. 9A is a schematic diagram illustrating a state of light passing through each pixel when the display image A is displayed on the liquid crystal panel 121 and the display image B is displayed on the liquid crystal panel 120. In the first embodiment, since the gradation value of each sub-pixel of the pixel of the liquid crystal panel 120 is common, the transmittance is shown for each pixel. The light emitted from the backlight 130 passes through the pixels of the liquid crystal panel 121, passes through the pixels of the liquid crystal panel 120, and reaches the user on the front surface of the liquid crystal panel 120, as indicated by the arrows in the figure.

  When the region 181 is viewed from the front (P1), the light emitted from the backlight 130 reaches the user through the path indicated by the arrow L1. In this case, the transmittance at the arrow L1 is a value obtained by multiplying the transmittance 1.00 on the liquid crystal panel 121 side by the transmittance 1.00 on the liquid crystal panel 120 side, and becomes 1.00.

  Further, when a region away from the region 181 in the region 182 is viewed from the front (P2), the light emitted from the backlight 130 reaches the user through the route indicated by the arrow L2. In this case, the transmittance at the arrow L2 is a value obtained by multiplying the transmittance 0.12 on the liquid crystal panel 121 side by the transmittance 1.00 on the liquid crystal panel 120 side, and becomes 0.12.

  Further, when the vicinity of the boundary between the region 181 and the region 182 in the region 181 is viewed obliquely (P4), the light emitted from the backlight 130 reaches the user through the path indicated by the arrow L4. In this case, the transmittance at the arrow L4 is 0.89, which is a value obtained by multiplying the transmittance 0.89 on the liquid crystal panel 121 side by the transmittance 1.00 on the liquid crystal panel 120 side. Therefore, even when the position of viewing bright pixels near the boundary is changed from P1 to P4, fluctuations in luminance viewed by the user are suppressed.

  When a region close to the region 181 in the region 182 is viewed from the front (P3), the light emitted from the backlight 130 reaches the user through the route indicated by the arrow L3. In this case, the transmittance at the arrow L3 is a value obtained by multiplying the transmittance 0.65 on the liquid crystal panel 121 side by the transmittance 0.17 on the liquid crystal panel 120 side to be 0.11. Therefore, when the region 182 is viewed from the front, the transmittance is approximately the same regardless of the distance from the region 181.

  FIG. 9B is a comparison diagram showing the transmittance of each pixel of the liquid crystal panels 120 and 121 when the transmittance of each pixel of the liquid crystal panel 120 is controlled based on the input image. In FIG. 9B, when the region 181 is viewed from the front (P1), and when the vicinity of the boundary between the region 181 and the region 182 is viewed obliquely (P4), the luminance that the user visually recognizes is Since this is the same as FIG. 9A, the description is omitted.

  When a region of the region 182 that is away from the region 181 is viewed from the front (P2), the light emitted from the backlight 130 reaches the user through the path indicated by the arrow L12. In this case, the transmittance at the arrow L2 is a value obtained by multiplying the transmittance 0.12 on the liquid crystal panel 121 side by the transmittance 0.12 on the liquid crystal panel 120 side, which is 0.01.

  Further, when the area close to the area 181 in the area 182 is viewed from the front (P3), the light emitted from the backlight 130 reaches the user through the path indicated by the arrow L13. In this case, the transmittance at the arrow L13 is a value obtained by multiplying the transmittance 0.65 on the liquid crystal panel 121 side by the transmittance 0.12 on the liquid crystal panel 120 side, which is 0.08. Therefore, the user feels that the luminance is changing in the vicinity of the region 181 even though the region 182 displaying the same luminance is viewed from the front.

  According to the display device 100 described in the first embodiment, an image obtained by performing smoothing processing on an input image is displayed on the liquid crystal panel on the backlight side, and the input image is based on the image displayed on the liquid crystal panel on the backlight side. The converted image is displayed on the liquid crystal panel on the user side. Therefore, it is possible to display an image based on the input image while suppressing a change in gradation due to a change in the line of sight, suppressing a variation in gradation due to the gradation conversion process, and maintaining a good gradation. Become.

  In this embodiment, the means for modulating light is a liquid crystal panel, but the liquid crystal panel is not limited as long as it is a transmissive display panel. Instead of a liquid crystal element, a transmissive display panel using a Micro Electro Mechanical Systems (MEMS) shutter may be used as means for changing the transmittance. In addition, the lighting device and the display panel on the lighting device side can be a self-luminous display panel using an organic EL element.

  In this embodiment, the smoothing processing unit 142 converts the gradation value of each pixel of the preprocessed image into an average value of the gradation values of the pixels included in the reference range with the pixel center, and displays the display image A. However, the conversion method is not limited to this. It is also possible to generate the display image A using the mean square value instead of the mean value. Further, the maximum gradation value (DMax), the minimum gradation value (Dmin), and the average value (Davg) of the gradation values of the pixels included in the reference range among the gradation values of the pixels included in the reference range. It is also possible to determine the gradation value of the pixel of the display image A using.

(Second embodiment)
FIG. 10 is a block diagram illustrating functional blocks of the display device 200 according to the second embodiment. Since the functional block having the same name as the first embodiment exhibits the same function except for the generation unit 240, the description thereof is omitted. The generation unit 240 includes a MaxRGB conversion unit 241, a smoothing processing unit 242, an expansion processing unit 243, a black pixel determination unit 244, and a selection unit 245.

  The MaxRGB conversion unit 241 performs processing similar to that of the functional block having the same name as that of the first embodiment on the input image to generate a luminance image. The MaxRGB conversion unit 241 outputs the luminance image to the smoothing processing unit 242 and the extension processing unit 243. The smoothing processing unit 242 performs a process similar to that of the functional block having the same name as that of the first embodiment on the luminance image to generate a smoothed image. The smoothing processing unit 242 outputs the smoothed image to the selection unit 245.

  The extension processing unit 243 acquires the luminance image output from the MaxRGB conversion unit 241 and performs extension processing. Specifically, the gradation value of each pixel of the luminance image is converted to the maximum gradation value among the gradation values of the pixels included in the 3 × 3 pixel reference range centered on the pixel, and the extended image Is generated. In other words, it can be said that the extended image is generated by converting the gradation value of each pixel of the luminance image into the maximum gradation value among the gradation values of the pixels adjacent to the pixel. The extension processing unit 243 outputs the extended image to the selection unit 245.

  The black pixel determination unit 244 determines whether or not the gradation values of the R, G, and B subpixels of each pixel of the input image are all zero. The black pixel determination unit 244 records the determination result for each pixel of the input image and generates a determination image. In the second embodiment, the black pixel determination unit 244 inputs 0 to the pixel when the gradation values of the R, G, and B subpixels of the pixel of the input image are all 0, otherwise In this case, 1 is input to the pixel. The black pixel determination unit 244 outputs the determination image to the selection unit 245.

  Note that the determination image may not be image data, and may be any result as long as it is possible to determine whether or not the gradation values of the sub-pixels of the pixel are all 0 for each pixel of the input image. For example, it is possible to use data describing the X coordinate and Y coordinate of each pixel of the input image and the determination result.

  For each pixel, the selection unit 245 selects either the smoothed image or the extended image according to the pixel value of the determination image, and generates the display image A. Specifically, when the pixel value of the determination image is 1 for each pixel of the display image A, the selection unit 245 selects the gradation value of the corresponding pixel of the smoothed image. When the pixel value of the determination image is 0, the selection unit 245 selects a corresponding pixel of the extended image. Then, the selection unit 245 sets the pixel value of the selected pixel as the gradation value of the corresponding pixel of the display image A. The selection unit 245 outputs the generated display image A to the liquid crystal panel 121 and the generation unit 250.

  Hereinafter, the operation of the display device 200 of the second embodiment will be described in detail. FIG. 11 is a schematic diagram showing an input image 280 in the second embodiment. The input image 280 has a region 281 and a region 282 with the XX straight line as a boundary. The gradation value of R, G, B of each pixel included in the region 281 is 255, and the gradation value of R, G, B of each pixel included in the region 282 is 0. That is, the input image 280 is divided into an area 281 displaying a white image and an area 282 displaying a black image on the left and right. The input image 280 is output from the image input unit 210 to the generation unit 240 and the generation unit 250.

  The input image 280 input to the generation unit 240 is input to the MaxRGB conversion unit 241 and the black pixel determination unit 244. The MaxRGB conversion unit 241 converts the input image 280 into a luminance image. Similar to the first embodiment, the MaxRGB conversion unit 241 uses the maximum gradation value of the R, G, and B subpixels included in each pixel of the input image 280 to obtain the maximum gradation value of the pixel in the luminance image. Convert to gradation value. In the second embodiment, in the luminance image, the gradation values of the pixels included in the area 281 are all 255, and the gradation values of the pixels included in the area 282 are all 0. The MaxRGB conversion unit 241 outputs the luminance image to the smoothing processing unit 242 and the extension processing unit 243.

  The smoothing processing unit 242 performs a conversion process similar to that in the first embodiment on the luminance image to generate a smoothed image. FIG. 12A is a schematic diagram showing an enlarged region of the preprocessed image corresponding to the region B of the input image 280 shown in FIG. The smoothing processing unit 242 converts the gradation value of each pixel of the luminance image into the maximum gradation value among the gradation values of the pixels included in the reference area of 5 × 5 pixels centering on the pixel, A preprocessed image is generated. As a result of the conversion of the gradation values, as shown in FIG. 12A, the gradation values of the pixels close to the area 281 among the pixels in the area 282 are converted into the gradation values of the pixels in the area 281.

  FIG. 12B is a schematic diagram showing an enlarged region of the smoothing image A corresponding to the region B of the input image 280 shown in FIG. The smoothing processing unit 142 converts the gradation value of each pixel of the preprocessed image into an average value of the gradation values of the pixels included in the reference region of 5 × 5 pixels centering on the pixel, and generates a smoothed image To do.

  As a result of the conversion of the gradation value, as shown in FIG. 12B, the gradation value of the pixel included in the area close to the area 281 among the pixels in the area 282 is increased. In other words, it can be said that the gradation value is converted so that the step of the gradation value between the region 282 and the region 281 changes smoothly and continuously. The smoothing processing unit 242 outputs the generated smoothed image to the selection unit 245.

  The extension processing unit 243 converts the gradation value of each pixel of the luminance image to generate an extended image. FIG. 13A is a schematic diagram showing an enlarged region of the luminance image corresponding to the region B of the input image 280 shown in FIG. The XX straight line is a boundary between the region 281 and the region 282. For the target pixel indicated by diagonal lines in FIG. 13A, the extension processing unit 243 has the maximum gradation value among the gradation values of the pixels included in the 3 × 3 reference region centered on the target pixel. Is converted to the gradation value of the target pixel. The extension processing unit 243 generates the extended image by performing the above-described processing on all the pixels of the luminance image.

  FIG. 13B is a schematic diagram illustrating an enlarged area of the extended image corresponding to the area B of the input image 280 illustrated in FIG. 11. By the gradation conversion processing by the extension processing unit 243, the gradation value of the pixels near the boundary of the region 282 is increased. The extension processing unit 243 outputs the extended image to the selection unit 245. The extension processing unit 243 is different from the smoothing processing unit 242 in that the 5 × 5 range is used as the reference range, and the luminance conversion is performed on the luminance image using the 3 × 3 range as the reference range. .

  The black pixel determination unit 244 determines whether each pixel of the input image 280 is a black pixel and generates a determination image. The black pixel determination unit 244 determines whether or not the gradation values of the R, G, and B subpixels of each pixel of the input image are all zero.

  In the second embodiment, since the gradation value of all the sub-pixels included in the region 281 is 255, the black pixel determination unit 244 is not a black pixel for all the pixels included in the region 281. Enter 1 to mean Further, since the gradation values of all the sub-pixels included in the region 282 are 0, the black pixel determination unit 244 inputs 0 indicating that the pixel is a black pixel to all the pixels included in the region 282. To do. The black pixel determination unit 244 outputs the determination image to the selection unit 245.

  The selection unit 245 selects a smoothed image or an extended image for each pixel based on the determination image, and generates a display image A2 having the gradation value of the corresponding pixel as the gradation value of the pixel. When the pixel value of the determination image corresponding to a certain pixel in the display image A2 is 1, the selection unit 245 sets the gradation value of the corresponding smoothing image pixel as the gradation value of a certain pixel in the display image A2. . Further, when the value of the pixel of the determination image corresponding to a certain pixel of the display image A2 is 0, the selection unit 245 determines the gradation value of the pixel of the corresponding extended image as the gradation value of the pixel of the display image A2. And

  FIG. 14 is a schematic diagram in which a region of the display image A2 corresponding to the region B of the input image 280 illustrated in FIG. 11 is enlarged. Since all the values of the pixels included in the determination image area 281 are 1, the gradation value of the smoothed image is input to the pixels included in the area 281 of the display image A2. Further, since all the values of the pixels included in the determination image area 282 are 1, the gradation value of the extended image is input to the pixels included in the area 282 of the display image A2. The selection unit 245 outputs the display image A2 to the generation unit 250 and the liquid crystal panel 221.

  The generation unit 250 generates a display image B2 using the input image 280 and the display image A2, and outputs the display image B2 to the liquid crystal panel 220. Since the method for generating the display image B2 is the same as that in the first embodiment, the description thereof is omitted.

  The liquid crystal panel 220 controls the transmittance of the liquid crystal element based on the display image B2. The liquid crystal panel 221 controls the transmittance of the liquid crystal element based on the display image A2. The light emitted from the backlight 230 to the liquid crystal panel 221 is modulated by the liquid crystal panel 221 and further modulated by the liquid crystal panel 220.

  FIG. 15A is a schematic diagram showing the transmittance of each pixel when an image is displayed on the liquid crystal panels 220 and 221 based on the description of the second embodiment. The pixels of the liquid crystal panel 220 have sub-pixels corresponding to R, G, and B, respectively, but the gradation values of the sub-pixels included in the same pixel are the same as in the first embodiment. The transmittance was shown. The relationship between the gradation value and the transmittance in each pixel of the liquid crystal panels 220 and 221 is the same as that in the first embodiment. The light emitted from the backlight 230 passes through the pixels of the liquid crystal panel 221, passes through the pixels of the liquid crystal panel 220, and reaches the user on the front surface of the liquid crystal panel 220 as indicated by arrows in the drawing.

  When the region 281 is viewed from the front (P1), the light emitted from the backlight 130 reaches the user through the path indicated by the arrow L1. In this case, the transmittance at the arrow L1 is a value obtained by multiplying the transmittance 1.00 on the liquid crystal panel 121 side by the transmittance 1.00 on the liquid crystal panel 120 side, and becomes 1.00.

  When a region of the region 282 that is away from the region 281 is viewed from the front (P2), the light emitted from the backlight 230 reaches the user through the path indicated by the arrow L2. In this case, the transmittance at the arrow L2 is a value obtained by multiplying the transmittance 0.05 on the liquid crystal panel 221 side and the transmittance 0.05 on the liquid crystal panel 220 side to be 0.0025. Therefore, by overlapping the liquid crystal panels 220 and 221, the light transmittance of the region 282 where the black image is displayed is reduced as compared with a case where one sheet passes through the liquid crystal panel.

  Further, when the vicinity of the boundary between the region 281 and the region 282 is viewed obliquely in the region 281 (P4), the light emitted from the backlight 230 reaches the user through the path indicated by the arrow L4. In this case, the transmittance at the arrow L4 is a value obtained by multiplying the transmittance 1.00 on the liquid crystal panel 221 side by the transmittance 1.00 on the liquid crystal panel 120 side, and becomes 1.00. Therefore, even when the position of viewing bright pixels near the boundary is changed from P1 to P4, fluctuations in luminance viewed by the user are suppressed.

  When an area close to the area 281 in the area 282 is viewed from the front (P3), the light emitted from the backlight 230 reaches the user through the path indicated by the arrow L3. In this case, the transmittance at the arrow L3 is a value obtained by multiplying the transmittance 0.05 on the liquid crystal panel 221 side by the transmittance 0.05 on the liquid crystal panel 220 side, which is 0.025. Therefore, the light transmittance of the region 282 is sufficiently reduced, and a good black image can be displayed.

  FIG. 15B is a comparison diagram showing the transmittance of each pixel of the liquid crystal panels 220 and 221 when the liquid crystal panel 221 is controlled based on the smoothed image. In FIG. 9B, when the area 281 is viewed from the front (P1) and when the area 282 is viewed from the front (P2), the luminance visually recognized by each user is the same as that in FIG. Therefore, explanation is omitted.

  When an area close to the area 281 in the area 282 is viewed from the front (P3), the light emitted from the backlight 230 reaches the user through the path indicated by the arrow L3. In this case, the transmittance at the arrow L3 is a value obtained by multiplying the transmittance 0.65 on the liquid crystal panel 221 side by the transmittance 0.05 on the liquid crystal panel 220 side to be 0.033. Similarly, when a portion of the region 282 that is close to the region 281 is viewed from the front, the transmittance of the liquid crystal panels 220 and 221 varies from pixel to pixel between P3 and P2. Therefore, the user feels that the luminance changes near the boundary with the region 281 even though the region 282 where the black image is displayed is viewed from the front. In other words, a high-brightness black float occurs in the black image displayed in the area close to the area 281 in the area 282.

  According to the display device 200 described in the second embodiment, when an image obtained by performing gradation conversion processing such as smoothing processing on the input image is used for the backlight side liquid crystal panel, the liquid crystal panel on the user side is used. An image to be displayed is generated using an image that has been subjected to gradation conversion processing. Therefore, it is possible to display an image based on the input image while suppressing a change in gradation due to a change in the line of sight, suppressing a variation in gradation due to the gradation conversion process, and maintaining a good gradation. Become.

  Furthermore, by reducing the reference range used for tone conversion for the area where the black image is input, it is possible to reduce the black floating of the black image adjacent to the bright area.

(Third embodiment)
FIG. 16 is a block diagram illustrating functional blocks of the display device 300 according to the second embodiment. Since the functional blocks having the same names as those of the first and second embodiments exhibit the same functions except for the generation unit 340, the description thereof is omitted. The generation unit 340 includes a binarization conversion unit 346 and an extension processing unit 343.

  The binarization conversion unit 346 binarizes the input image and outputs the binarized image to the extension processing unit 243. The binarization conversion unit 346 sets the gradation value of the pixel to 0 when the gradation values of the sub-pixels corresponding to R, G, and B of each pixel of the input image are all equal to or less than a predetermined threshold value. Convert. Also, the binarization conversion unit 346 converts the gradation value of the pixel to 255 when it has a sub-pixel having a gradation value larger than a predetermined threshold value. The binarization conversion unit 346 outputs the binarized image to the extension processing unit 243.

  The extension processing unit 343 performs an extension process on the binarized image to generate a display image A3. The extension process is the same process as in the second embodiment, and a description thereof will be omitted. The extension processing unit 343 outputs the display image A3 to the generation unit 350 and the liquid crystal panel 321.

  According to the third embodiment, when the input image 280 shown in FIG. 11 is input, a display image A3 similar to the display image A2 obtained in the second embodiment can be obtained more easily. It becomes. Therefore, by reducing the reference range used for tone conversion in the area where the black image is input, it is possible to reduce the black floating of the black image adjacent to the bright area.

  When the input image 180 shown in FIG. 3 is input, the display image A3 is an all-white image in which the gradation value of all pixels is 255. In this case, the display image B3 generated by the generation unit 350 is the same image as the input image 180. Therefore, even when the user tilts his / her line of sight with respect to the boundary between the area 181 and the area 182, the transmittance of the liquid crystal panel 320 does not change with respect to the line-of-sight direction. Can do.

  According to the third embodiment, when an image obtained by performing gradation conversion processing such as smoothing processing on the input image is used for the backlight-side liquid crystal panel, the image displayed on the user-side liquid crystal panel is It is generated using an image that has been subjected to a tone conversion process. Therefore, it is possible to display an image based on the input image while suppressing a change in gradation due to a change in the line of sight, suppressing a variation in gradation due to the gradation conversion process, and maintaining a good gradation. Become.

  Furthermore, by reducing the reference range used for tone conversion for the area where the black image is input, it is possible to reduce the black floating of the black image adjacent to the bright area.

DESCRIPTION OF SYMBOLS 100 Display apparatus 180 Input image 181, 182 Area | region 140, 150 Generation part 120, 121 Liquid crystal panel 130 Backlight

Claims (14)

A process of increasing the gradation value of a pixel in a predetermined area adjacent to the first area among the second areas adjacent to the first area of the input image and having a gradation value lower than that of the first area is performed. First generating means for generating a first image;
Second generation means for generating a second image by performing a process of converting the gradation value of the input image using the gradation value of the first image;
Illumination means for irradiating light;
First modulation means for modulating light emitted from the illumination means based on the first image;
Second modulation means for further modulating the light modulated by the first modulation means based on the second image;
A display device comprising:   The second generation means uses the ratio between the maximum gradation value that the first image can take and the gradation value of the first image, and the gradation value of the input image, to calculate the scale of the second image. The display device according to claim 1, wherein a tone value is determined. The first generation means converts the gradation value of the pixel using gradation values of a plurality of pixels included in a reference range including each pixel of the input image,
The display device according to claim 1, wherein the reference range used for gradation conversion of the pixel becomes smaller as the gradation value of the pixel is lower.   The first generation unit converts the gradation value of each pixel of the input image into an average value of gradation values of a plurality of pixels included in a reference range including the pixel. The display device described. When the gradation value of each pixel of the input image is 0, the first generation unit uses the gradation value of the pixel included in the first reference range centered on the pixel to Convert the tone value of one image pixel,
When the gradation value of each pixel of the input image is not 0, the gradation value of the pixel included in the second reference range that is wider than the first reference range centered on the pixel is used. The display device according to claim 1, wherein a gradation value of a pixel of one image is converted. Determination means for determining whether or not the gradation value of each pixel of the input image is 0;
The first generation means includes
First processing means for performing a gradation conversion process on a gradation value of each pixel of the input image using a gradation value of a pixel included in the first reference range;
Second processing means for performing gradation conversion processing on the gradation value of each pixel of the input image using the gradation value of the pixel included in the second reference range;
For the pixel whose gradation value is determined to be 0 by the determination means, the result of the gradation conversion process by the first processing means is selected as the corresponding pixel of the first image,
Selecting means for selecting, as a corresponding pixel of the first image, a result of gradation conversion processing by the second processing means for a pixel for which the gradation value is determined not to be 0 by the determination means; The display device according to claim 5.   The display according to claim 5 or 6, wherein the first reference range includes pixels to which the first generation unit performs gradation conversion processing and eight pixels adjacent to the pixels. apparatus. When the gradation value of each pixel of the input image is equal to or less than a predetermined threshold, the gradation value of the pixel is changed to 0, and the gradation value of each pixel of the input image is larger than the predetermined threshold A conversion means for changing the gradation value of the pixel to a predetermined value,
5. The display according to claim 1, wherein the first generation unit performs a process of converting a gradation value of a pixel of the input image converted by the conversion unit. apparatus.   The first generation unit performs a process of converting the gradation value of the pixel of interest using the pixel of interest to which the first generation unit performs gradation conversion processing and eight pixels adjacent to the pixel. The display device according to claim 8. The first modulation means and the second modulation means have a plurality of pixels that can individually control the light transmittance,
The second modulation means can individually set light transmittance for the red subpixel, the green subpixel, and the blue subpixel of each of the plurality of pixels. The display device according to any one of claims 1 to 8, wherein the display device is characterized. The input image is an image having a gradation value corresponding to each sub-pixel,
The first generation means converts the gradation value of each pixel of the input image to the largest gradation value among the gradation values of the sub-pixels included in the pixel,
The display device according to claim 10, wherein a process of converting a gradation value of a pixel of the converted input image is performed. The first modulation means is a liquid crystal panel;
The display device according to claim 1, wherein the second modulation unit is a liquid crystal panel. A gradation conversion process is performed to increase the gradation value of a pixel in a region adjacent to the first region, out of the second region having a gradation value lower than that of the first region adjacent to the first region of the input image. A gradation conversion step of generating a first image;
Using the gradation value of the input image and the gradation value of the first image, determining a gradation value of a pixel of the second image corresponding to the pixel, and generating the second image;
A first output step of outputting the first image to a first modulation means for modulating light emitted from the illumination means;
A control method for a display device, comprising: a second output step of outputting the second image to a second modulation unit that further modulates the light modulated by the first modulation unit.   A program capable of being executed by a computer in each step of the display device control method according to claim 13.

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