JP2013033088A - Light-emitting device, display device, control device, control method and control program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a display image with bright colors and high contrast.SOLUTION: A light-emitting device 10 includes: a plurality of light emitting sections 7 at least one of which is arranged for each of a plurality of division portions where an optical modulation section 3 for modulating illumination light on the basis of image data to display images is divided and emits illumination light to be irradiated on the optical modulation section 3; a color saturation determination section 4 with a luminance estimation function for determining color saturation of a portion corresponding to the division portion of the images shown by the image data and estimating the luminance of the portion for every division portion; and a light emitting control data generation section 5 for controlling the luminance of the light emitting section 7 corresponding to the division portion on the basis of the color saturation determination result and the luminance estimation result for every division portion.

Description

  The present invention relates to a light emitting device, a display device, a control device, a control method, and a control program.

  A light-receiving light modulation element such as a liquid crystal panel and a light source that irradiates the light modulation element with illumination light. The light modulation element modulates the illumination light from the light source according to the input image data and displays an image. There is a display device (see, for example, Patent Document 1).

  The display device described in Patent Literature 1 detects the amount of a chromatic color component of an image represented by image data, and controls the luminance of a light source based on the amount of the chromatic color component. According to this display device, a brightly displayed image can be obtained without increasing the color purity of the color filter by displaying brighter colors with high saturation.

Japanese Patent No. 3922306

  By the way, in a display device using light modulation means, there is a desire to obtain a display image with more vivid colors and high contrast.

  An object of the present invention is to provide a light emitting device, a display device, a control device, a control method, and a control program capable of obtaining a vivid and high-contrast display image.

The light emitting device according to the present invention is
At least one is arranged for each of the plurality of divided portions obtained by dividing the light modulation means for displaying the image by modulating the illumination light based on the image data, and emits the illumination light irradiated to the light modulation means A plurality of light emitting means;
Saturation determination means with a luminance estimation function for determining the saturation of the portion corresponding to the divided portion of the image represented by the image data for each divided portion, and estimating the luminance of the portion;
Control means for controlling the luminance of the light emitting means corresponding to the divided portion based on the determination result of the saturation and the estimation result of the luminance for each divided portion;
It is characterized by providing.

Moreover, the display device according to the present invention includes:
The light emitting device;
The light modulation means for displaying an image by modulating the illumination light from the light emitting device;
It is characterized by providing.

Further, the control device according to the present invention includes:
A control device used in a display device including a light modulation unit that modulates illumination light based on image data to display an image,
For each of a plurality of divided portions obtained by dividing the light modulation means, with a luminance estimation function for determining the saturation of the portion corresponding to the divided portion of the image represented by the image data and estimating the luminance of the portion Saturation determination means;
Control means for controlling the luminance of the illumination light corresponding to the divided portion based on the determination result of the saturation and the estimation result of the luminance for each divided portion;
It is characterized by providing.

Moreover, the control method according to the present invention includes:
At least one light modulating unit that modulates illumination light based on image data to display an image and each of a plurality of divided portions obtained by dividing the light modulating unit is disposed and irradiated to the light modulating unit. A control method used for a display device comprising a plurality of light emitting means for emitting the illumination light,
A determination step for determining the saturation of a portion corresponding to the divided portion of the image represented by the image data for each divided portion and estimating the luminance of the portion;
A control step for controlling the luminance of the light emitting means corresponding to the divided portion based on the determination result of the saturation and the estimation result of the luminance for each divided portion;
It is characterized by having.
The control program according to the present invention is:
At least one light modulating unit that modulates illumination light based on image data to display an image and each of a plurality of divided portions obtained by dividing the light modulating unit is disposed and irradiated to the light modulating unit. A control program used in a display device comprising a plurality of light emitting means for emitting the illumination light,
A determination step for determining the saturation of a portion corresponding to the divided portion of the image represented by the image data for each divided portion and estimating the luminance of the portion;
A control step for controlling the luminance of the light emitting means corresponding to the divided portion based on the detection result of the saturation and the estimated result of the luminance for each divided portion;
Is executed by a computer.

  According to the present invention, it is possible to provide a light emitting device, a display device, a control device, a control method, and a control program capable of obtaining a vivid and high-contrast display image.

3 is a block diagram illustrating a configuration of a display device including the light-emitting device according to Embodiment 1. FIG. It is a figure which shows the example of the division | segmentation of a light modulation part. It is a figure which shows the other example of the division | segmentation of an optical modulation part. It is a figure which shows the other example of the division | segmentation of an optical modulation part. It is a block diagram which shows the structural example of the saturation determination part with a brightness | luminance estimation function. It is a flowchart which shows the process example of the saturation determination part with a brightness | luminance estimation function. It is a figure which shows an example of the relationship between the saturation determination data and the light emission control data for demonstrating the process of the light emission control data generation part. It is a figure which shows an example of the relationship between brightness | luminance estimation data and light emission control data for demonstrating the process of the light emission control data generation part. FIG. 6 is a diagram illustrating a color reproduction range of the display device for explaining the operation of the display device according to the first embodiment. FIG. 6 is a diagram illustrating a color reproduction range of the display device for explaining the operation of the display device according to the first embodiment. FIG. 6 is a diagram illustrating a color reproduction range of the display device for explaining the operation of the display device according to the first embodiment. FIG. 6 is a diagram illustrating a color reproduction range of the display device for explaining the operation of the display device according to the first embodiment. It is a block diagram which shows the other structural example of the saturation determination part with a luminance estimation function. It is a flowchart which shows the other example of a process of the saturation determination part with a luminance estimation function. It is a block diagram which shows the other structural example of the saturation determination part with a luminance estimation function. It is a flowchart which shows the other example of a process of the saturation determination part with a luminance estimation function. 7 is a block diagram illustrating a configuration of a display device including a light emitting device according to Embodiment 2. FIG. 6 is a flowchart illustrating a processing example of a light emission control data adjustment unit of the light emitting device according to the second embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
Embodiment 1 FIG.
FIG. 1 is a block diagram illustrating a configuration of a display device 100 including the light emitting device 10 according to the first embodiment. The display device 100 is a device that displays an image by modulating light based on input image data. In FIG. 1, the display device 100 includes an input terminal 1, a receiver 2, a light modulator 3, and a light emitting device 10.

  The input terminal 1 is a terminal that receives an input of an image signal of a predetermined format used in a television or a computer.

  The receiving unit 2 receives the image signal via the input terminal 1, and the received image signal is an image composed of color data (or gradation values) of R (red), G (green), and B (blue). Data or image data composed of luminance and color difference data is converted and output. For example, the receiving unit 2 includes an A / D converter when an analog image signal is input, and a predetermined demodulator when an analog or digital modulated image signal is input. Consists of. The image data output from the receiving unit 2 is supplied to the light modulating unit 3 and the light emitting device 10.

  The light modulation unit 3 modulates the illumination light from the light emitting device 10 based on the image data from the reception unit 2 and displays an image on the screen, and is also called an image display unit. Specifically, the light modulation unit 3 is configured by a display device such as a liquid crystal panel or a DMD (digital mirror device) in which minute mirror elements are arranged.

  The light emitting device 10 is a device that irradiates the light modulation unit 3 with illumination light, and is also called a light emitting module. The light emitting device 10 includes a plurality of light emitting units 7 and a control device 8.

  The light emitting unit 7 is arranged at least one for each of a plurality of divided portions obtained by dividing the light modulation unit 3 (or its screen), and emits illumination light that is irradiated onto the light modulation unit 3 to be modulated. 2, 3, and 4 show examples of the division of the light modulation unit 3, respectively. In FIG. 2, the rectangular screen of the light modulation unit 3 has a grid shape (matrix shape) of m rows and n columns (m and n are integers of 2 or more, and m = 8 and n = 12 in FIG. 2). For example, at least one light emitting unit 7 is arranged immediately below each cell. In FIG. 3, the rectangular screen of the light modulation unit 3 is divided into two regions at the center in the horizontal direction, and j regions (j is an integer of 1 or more and j = 5 in FIG. 3) in the vertical direction. For example, the light emitting units 7 are arranged in the vertical direction at both ends (left and right ends) in the horizontal direction of the light modulation unit 3. In FIG. 4, the rectangular screen of the light modulation unit 3 is divided into two regions at the center in the vertical direction, and k regions (k is an integer of 1 or more, k = 9 in FIG. 4) in the horizontal direction. For example, the light emitting units 7 are arranged in the horizontal direction at both ends (upper and lower ends) in the vertical direction of the light modulation unit 3.

  For each of the divided portions, the control device 8 determines the saturation (or the amount of the chromatic color component) of the portion corresponding to the divided portion (that is, the image displayed in the divided portion) in the image represented by the image data. And the luminance of the part is estimated, and the luminance of the illumination light irradiated to the divided part of the light modulation unit 3 is controlled based on the determination result of the saturation and the estimation result of the luminance. In the example of FIG. 1, the control device 8 includes a saturation determination unit 4 with a luminance estimation function, a light emission control data generation unit 5, and a light emission drive control unit 6.

  A saturation determination unit with luminance estimation function (hereinafter referred to as “saturation determination unit”) 4 is an image represented by image data for each divided portion of the light modulation unit 3 based on image data from the reception unit 2. Among them, the saturation of the part corresponding to the divided part is determined, and the luminance of the part is estimated. Specifically, for each divided portion, the saturation determination unit 4 detects the color component of the image portion corresponding to the divided portion, generates saturation determination data indicating the determination result of saturation, Luminance estimation data indicating the estimation result is generated. The saturation determination data for each divided portion and the luminance estimation data for each divided portion generated by the saturation determination unit 4 are supplied to the light emission control data generation unit 5.

  The light emission control data generation unit 5 controls the luminance of the illumination light corresponding to the divided portion based on the saturation determination result and the luminance estimation result by the saturation determination unit 4 for each divided portion. Specifically, the light emission control data generation unit 5 controls the luminance of each of the plurality of light emitting units 7 based on the saturation determination data for each divided portion and the luminance estimation data for each divided portion. The light emission control data is generated and output. For example, the light emission control data generation unit 5 controls the light emission control data for controlling the luminance of the light emitting unit 7 corresponding to the divided portion based on the saturation determination data and the luminance estimation data of the divided portion for each divided portion. Is generated. The light emission control data for each divided portion output from the light emission control data generation unit 5 is supplied to the light emission drive control unit 6.

  Based on the light emission control data from the light emission control data generation unit 5, the light emission drive control unit 6 drives and controls the plurality of light emission units 7 with luminance according to the light emission control data. Specifically, the light emission drive control unit 6 generates a light emission drive signal for causing each light emitting unit 7 to emit light based on the light emission control data for each divided portion, and supplies the light emission drive signal to each light emitting unit 7. More specifically, the light emission drive control unit 6 sends a light emission drive signal corresponding to the light emission control data of the divided part to each of the one or more light emitting units 7 corresponding to the divided part for each divided part. Output. The light emission drive signal is, for example, a signal that modulates the drive current flowing through the light emitting unit 7 or a signal that drives the light emitting unit 7 in pulse width.

  Each of the plurality of light emitting units 7 is driven by a light emission drive signal from the light emission drive control unit 6, emits light with luminance according to the light emission drive signal, and irradiates the light modulation unit 3 with illumination light.

  In the above configuration example, the luminance of the illumination light (specifically, based on the determination result of the saturation and the estimation result of the luminance by the light emission control data generation unit 5 or by the light emission control data generation unit 5 and the light emission drive control unit 6). A control means for controlling the brightness of the light emitting unit 7 is realized.

  In one aspect, from the viewpoint of obtaining a colorful display image, the control device 8 controls the luminance of the illumination light corresponding to the divided portion so that it becomes brighter as the saturation of the image corresponding to the divided portion increases. . Further, from the viewpoint of obtaining a high-contrast display image by suppressing black floating, the control device 8 darkens the luminance of the illumination light corresponding to the divided portion as the luminance of the image corresponding to the divided portion is lower. To control. Further, from the viewpoint of brightly displaying a portion close to white and obtaining a high-contrast display image, the control device 8 increases the luminance of the illumination light corresponding to the divided portion as the luminance of the image corresponding to the divided portion increases. Control to be.

  Specifically, for each divided portion, the saturation determination unit 4 has a predetermined saturation for an image portion corresponding to the divided portion (that is, a portion corresponding to the divided portion in the image represented by the image data). It is determined whether it is a high saturation portion (or chromatic color portion) greater than the level, and the determination result is output to the light emission control data generation unit 5 as saturation determination data. In addition, for each divided portion, the saturation determination unit 4 has a low saturation low luminance portion (or low luminance) in which the image portion corresponding to the divided portion has a saturation lower than a predetermined level and a luminance lower than the predetermined level. It is determined whether or not it is a chromatic low luminance part), and the determination result is output to the light emission control data generation unit 5 as saturation determination data and luminance estimation data. For example, if the saturation determination unit 4 determines that the portion is a low saturation portion and a low luminance portion, saturation determination data indicating that the portion is a low saturation portion and luminance estimation data indicating that the portion is a low luminance portion are obtained. Output. In addition, for each divided portion, the saturation determination unit 4 has a low-saturation high-luminance portion (or a low-luminance portion) in which an image portion corresponding to the divided portion has a saturation lower than a predetermined level and a luminance higher than a predetermined level. It is determined whether it is a chromatic high-intensity part), and the determination result is output to the light emission control data generation unit 5 as saturation determination data and luminance estimation data. For example, when the saturation determination unit 4 determines that the portion is a low saturation high luminance portion, the saturation determination data indicating the low saturation portion and luminance estimation data indicating the high luminance portion are obtained. Output.

  And the light emission control data generation part 5 controls the brightness | luminance of the light emission part 7 corresponding to the said division part based on the saturation determination data and brightness | luminance estimation data of the said division part for every division part. Specifically, when the image portion corresponding to the divided portion is a high saturation portion, the light emission control data generation unit 5 compares the light emitting portion corresponding to the divided portion as compared with the case where the saturation is smaller than a predetermined level. Increase the brightness of 7. Further, the light emission control data generation unit 5 has a case where the image portion corresponding to the divided portion is a low-saturation and low-brightness portion, compared with a case where the saturation is smaller than a predetermined level and the luminance is higher than a predetermined level. Thus, the luminance of the light emitting unit 7 corresponding to the divided portion is lowered. Further, the light emission control data generating unit 5 has a case where the image portion corresponding to the divided portion is a low saturation high luminance portion, compared with a case where the saturation is lower than a predetermined level and the luminance is lower than the predetermined level. Thus, the luminance of the light emitting unit 7 corresponding to the divided portion is increased.

  For example, the light emission control data generation unit 5 is a portion where the image portion corresponding to the divided portion under attention is not a high saturation portion, a low saturation low luminance portion, or a low saturation high luminance portion (or a low saturation medium luminance portion). In some cases, light emission control data for illuminating the light emitting unit 7 corresponding to the divided part of interest with standard luminance is output. When the light emitting unit 7 is a high saturation portion, the light emitting unit 7 is brighter than the standard luminance. When the light emission control data to be lit is output and the low saturation low luminance part is output, the light emission control data to illuminate the light emitting unit 7 darker than the standard luminance is output. The light emission control data for making the light emitting unit 7 shine brighter than the standard luminance is output.

  FIG. 5 is a block diagram illustrating a configuration example of the saturation determination unit 4. Hereinafter, a configuration example of the saturation determination unit 4 will be described with reference to FIG. 5 includes a maximum value detection unit 11, a minimum value detection unit 12, a maximum value average value calculation unit 13, a minimum value average value calculation unit 14, a subtraction unit 15, and a chromatic color component determination threshold value storage. Unit 16, low luminance component determination threshold storage unit 17, high luminance component determination threshold storage unit 18, and divided partial component determination unit 19.

  The maximum value detection unit 11 receives the image data from the reception unit 2, and for each pixel in the portion corresponding to the divided portion of interest in the image data, the colors of R, G, and B of the sub-pixels constituting the pixel Among the data, the value of the maximum value is output to the maximum value average value calculation unit 13 as maximum value data. The maximum value average value calculation unit 13 calculates the average value of the maximum value data of the pixels in the portion corresponding to the divided portion of interest in the image data as the maximum value average value. The calculated maximum average value is supplied to the subtraction unit 15 and the divided partial component determination unit 19.

  The minimum value detection unit 12 receives the image data from the reception unit 2, and for each pixel in the portion corresponding to the divided portion of interest in the image data, the R, G, and B colors of the sub-pixels constituting the pixel Of the data, the smallest value is output as minimum value data to the minimum value average value calculation unit 14. The minimum value average value calculation unit 14 calculates the average value of the minimum value data of the pixels in the portion corresponding to the divided portion of interest in the image data as the minimum value average value. The calculated minimum average value is supplied to the subtraction unit 15 and the divided partial component determination unit 19.

  The subtraction unit 15 calculates a difference value between the maximum value average value and the minimum value average value of the divided portion of interest by subtracting the output of the minimum value average value calculation unit 14 from the output of the maximum value average value calculation unit 13. And output to the divided partial component determination unit 19.

  The chromatic color component determination threshold storage unit 16 stores a preset chromatic color component determination threshold, and the low luminance component determination threshold storage unit 17 stores a preset low luminance component determination threshold. The high luminance component determination threshold storage unit 18 stores a preset high luminance component determination threshold.

  The divided partial component determination unit 19 includes a maximum value average value from the maximum value average value calculation unit 13, a minimum value average value from the minimum value average value calculation unit 14, a difference value from the subtraction unit 15, and a chromatic color component. The chromatic color component determination threshold stored in the determination threshold storage unit 16, the low luminance component determination threshold stored in the low luminance component determination threshold storage unit 17, and the high luminance component stored in the high luminance component determination threshold storage unit 18 Based on the determination threshold, the saturation determination data and the luminance estimation data of the divided portion under attention are generated and output.

  FIG. 6 is a flowchart illustrating a processing example of the saturation determination unit 4. Hereinafter, a processing example of the saturation determination unit 4 will be described with reference to FIG. FIG. 6 shows an example of a processing procedure of the divided partial component determination unit 19 of the saturation determination unit 4 configured as shown in FIG.

  First, the divided part component determination unit 19 receives an input of the maximum value average value, minimum value average value, and difference value of both average values of the divided part of interest (ST1).

  Next, the divided part component determination unit 19 determines whether or not the difference value between the maximum value average value and the minimum value average value of the divided part of interest is greater than or equal to the chromatic color component determination threshold value (ST2). The difference value between the maximum value average value and the minimum value average value of the divided portion represents the amount (or saturation) of the chromatic color component of the image portion corresponding to the divided portion, and the saturation value (or the maximum value) increases as the difference value increases. It is considered that the color purity of

  When the difference value is equal to or greater than the chromatic color component determination threshold (ST2: YES), the divided portion component determination unit 19 determines the image portion corresponding to the focused divided portion as the high saturation portion, and is the high saturation portion. Is output, and brightness estimation data indicating that neither low-saturation, low-luminance part nor low-saturation, high-brightness part is output (ST3).

  On the other hand, when the difference value is smaller than the chromatic color component determination threshold value (ST2: NO), the divided portion component determination unit 19 determines whether the maximum average value of the divided portion of interest is smaller than the low luminance component determination threshold value. Is determined (ST4).

  As a result of the determination, when the maximum average value is smaller than the low luminance component determination threshold value (ST4: YES), the divided portion component determining unit 19 displays the image portion corresponding to the focused divided portion with low saturation and low luminance. It is determined as a portion, and saturation determination data and luminance estimation data indicating a low saturation and low luminance portion are output (ST5). Specifically, the divided partial component determination unit 19 outputs saturation determination data indicating a low saturation portion and luminance estimation data indicating a low luminance portion.

  On the other hand, when the maximum value average value is larger than the low luminance component determination threshold value (ST4: NO), the divided portion component determination unit 19 has the minimum value average value of the target divided portion larger than the high luminance component determination threshold value. (ST6).

  As a result of the determination, when the minimum average value is larger than the high-luminance component determination threshold (ST6: YES), the divided part component determination unit 19 determines that the image part corresponding to the divided part of interest has a low saturation and high luminance. It is determined as a portion, and saturation determination data and luminance estimation data indicating that the portion is a low saturation and high luminance portion are output (ST7). Specifically, the divided partial component determination unit 19 outputs saturation determination data indicating a low saturation portion and luminance estimation data indicating a high luminance portion.

  On the other hand, when the minimum average value is smaller than the high luminance component determination threshold (ST6: NO), the divided partial component determination unit 19 determines that neither the high saturation portion, the low saturation portion, or the low saturation high luminance portion is present. The saturation determination data and luminance estimation data shown are output (ST8). Specifically, the divided part component determination unit 19 performs saturation determination data indicating that the portion is not a high saturation portion (or is a low saturation portion), and is not a low luminance portion or a high luminance portion (or a medium luminance portion). Brightness estimation data indicating that the

  The saturation determination unit 4 performs the above processing for each of the plurality of divided regions, and outputs saturation determination data and luminance estimation data for each divided portion. Further, for example, the saturation determination unit 4 generates and outputs the saturation determination data and the luminance estimation data for each divided portion at a predetermined cycle such as one screen (one frame) unit.

  In addition to the information on whether or not the portion is a high saturation portion or the like, the saturation determination unit 4 displays the degree information indicating how much the threshold has been exceeded or how far the threshold has not been reached. It may be included in the data. For example, in addition to the information indicating that the saturation portion is a high saturation portion, the saturation determination unit 4 displays the degree information indicating the difference between the difference value between the maximum average value and the minimum average value and the chromatic color component determination threshold. It may be included in the determination data. Further, the saturation determination unit 4 may include, in addition to the information indicating that it is a low-luminance part, degree information indicating the difference between the maximum average value and the low-luminance component determination threshold in the luminance estimation data. Further, the saturation determination unit 4 may include degree information indicating the difference between the minimum average value and the high luminance component determination threshold in the luminance estimation data, in addition to the information indicating the high luminance portion.

  Also, the low luminance component determination threshold and the high luminance component determination threshold are set to the same value, and the portion determined as the low saturation portion is always either the low saturation low luminance portion or the low saturation high luminance portion. It is also possible to make the settings included in the above.

  The order of the above processes may be changed as appropriate. For example, the order of the determination based on the chromatic color component determination threshold, the determination based on the low luminance component determination threshold, and the determination based on the high luminance component determination threshold may be changed as appropriate. In step ST4, the divided partial component determination unit 19 has the maximum average value smaller than the low luminance component determination threshold value, and the difference value between the maximum value average value and the minimum value average value is smaller than the chromatic color component determination threshold value. In step ST6, it is determined whether the minimum value average value is larger than the high luminance component determination threshold value and the difference value between the maximum value average value and the minimum value average value is smaller than the chromatic color component determination threshold value. May be. In this case, the divided partial component determination unit 19 proceeds from step ST1 to step ST4. If the determination result in step ST4 is YES, the process proceeds to step ST5. If NO, the process proceeds to step ST6. If the determination result in step ST6 is YES, the process proceeds to step ST7, and if NO, the process proceeds to step ST2. If the determination result in step ST2 is YES, the process proceeds to step ST3, and if NO, the process proceeds to step ST8.

  FIG. 7 is a diagram illustrating an example of the relationship between the saturation determination data and the light emission control data for explaining the processing of the light emission control data generation unit 5. FIG. 8 is a diagram illustrating an example of the relationship between the luminance estimation data and the light emission control data for explaining the processing of the light emission control data generation unit 5. Hereinafter, an example of processing of the light emission control data generation unit 5 will be described with reference to FIGS. 7 and 8.

  The light emission control data generation unit 5 makes the light emission unit 7 brighter than the standard luminance when the saturation determination data from the saturation determination unit 4 indicates the high saturation portion for the divided portion of interest. The light emission control data to be lit is output, and the light emitting unit 7 corresponding to the divided part of interest is lit brighter than the standard luminance. Specifically, the light emission control data generation unit 5 outputs light emission control data b that is larger than the light emission control data a that causes the light emitting unit 7 to emit light with standard luminance. Here, when the saturation determination data includes degree information indicating the difference between the difference value between the maximum average value and the minimum average value and the chromatic color component determination threshold, the light emission control data generation unit 5 performs the degree information. The light emission control data may be determined as a value between a and b based on. For example, as shown in FIG. 7, the light emission control data generation unit 5 may gently change the light emission control data from a to b according to the degree information so that the luminance increases as the degree information increases. .

  On the other hand, if the saturation determination data from the saturation determination unit 4 indicates that it is not a high saturation portion (or a low saturation portion) for the divided portion of interest, the light emission control data generation unit 5 The light emission control data is determined based on the luminance estimation data as follows.

  The light emission control data generation unit 5 makes the light emission unit 7 darker than the standard luminance when the luminance estimation data from the saturation determination unit 4 indicates a low luminance part for the divided part of interest. The light emission control data to be lit is output, and the light emitting unit 7 corresponding to the divided part of interest is made to shine darker than the standard luminance. Specifically, the light emission control data generation unit 5 outputs light emission control data c that is smaller than the light emission control data a that causes the light emitting unit 7 to emit light with standard luminance. Here, when the luminance estimation data includes degree information indicating a difference between the maximum average value and the low luminance component determination threshold, the light emission control data generation unit 5 sets the light emission control data as a based on the degree information. A value between c may be determined. For example, as shown in FIG. 8, the light emission control data generation unit 5 may gently change the light emission control data from a to c according to the degree information so that the luminance decreases as the degree information increases. .

  In addition, when the luminance estimation data from the saturation determination unit 4 indicates that the divided portion of interest is a high luminance portion, the light emission control data generation unit 5 emits light from the standard luminance. The light emission control data for brightening the light is output, and the light emitting unit 7 corresponding to the divided part of interest is made brighter than the standard luminance. Specifically, the light emission control data generation unit 5 outputs light emission control data d that is larger than the light emission control data a that causes the light emitting unit 7 to emit light with standard luminance. Here, when the luminance estimation data includes degree information indicating the difference between the minimum average value and the high luminance component determination threshold, the light emission control data generation unit 5 sets the light emission control data as a based on the degree information. A value between d may be determined. For example, as shown in FIG. 8, the light emission control data generation unit 5 may gently change the light emission control data from a to d in accordance with the degree information so that the luminance increases as the degree information increases. .

  Further, the light emission control data generation unit 5 indicates that the luminance estimation data from the saturation determination unit 4 is neither a low luminance portion nor a high luminance portion (or a medium luminance portion) for the divided portion of interest. In this case, the light emission control data a for causing the light emitting unit 7 to emit light with standard luminance is output, and the light emitting unit 7 corresponding to the divided portion of interest is made to emit light with standard luminance.

  The light emission control data generation unit 5 performs the above processing for each of the plurality of divided regions, and outputs light emission control data for each divided portion. Further, for example, the light emission control data generation unit 5 generates and outputs the light emission control data for each divided portion at a predetermined cycle such as one screen (one frame) unit.

  Note that the light emission control data d in FIG. 8 may be set to a value different from the light emission control data b in FIG. 7 or may be set to the same value. Further, either one of the light emission control data c and d in FIG. 8 may be set to the same value as the light emission control data a.

  9, FIG. 10, FIG. 11, and FIG. 12 are diagrams each showing a color reproduction range of the display device 100 for explaining the operation of the display device 100 according to the present embodiment. Hereinafter, the operation of the display device 100 will be described with reference to FIGS.

  FIG. 9 shows a color reproduction range of the display device 100 when the light emitting unit 7 emits light based on the light emission control data a, that is, when the light emitting unit 7 emits light with standard luminance. Referring to FIG. 9, when the luminance levels of the three sub-pixels of R, G, and B in the light modulation unit 3 are 0, the brightness (or brightness) and saturation are 0, and black is obtained. When the luminance level of a single color sub-pixel among the three colors is increased from this state, the saturation and brightness increase, and when the sub-pixel is fully lit, a pure color (the color with the highest saturation) is obtained. If the luminance levels of the remaining two sub-pixels are simultaneously increased from this state, the brightness increases while the saturation decreases, and when the two sub-pixels of the two colors are fully illuminated, white is obtained. If the luminance of the three color sub-pixels is simultaneously lowered from this state, the lightness is decreased with the saturation being 0, white of an intermediate luminance level is obtained, and when the luminance level of the three color sub-pixels becomes 0, A black color is obtained. When the light emitting unit 7 is always driven with the light emission control data a, the color reproduction range is constant within the range surrounded by the lines in FIG.

  FIG. 10 shows a color reproduction range of the display device 100 when the light emitting unit 7 emits light based on the light emission control data b, that is, when the light emitting unit 7 emits light with a brightness brighter than the standard. In display device 100 according to the present embodiment, as shown in FIG. 7, in the divided portion where the saturation is high (or the amount of the chromatic color component is large), that is, the divided portion which is the high saturation portion, the light emission control data is stored. The value b is larger than the standard value a, and the luminance of the illumination light increases. As a result, as shown by the solid line in FIG. 10, the high-saturation portion (chromatic color region) with high saturation is displayed brighter than in the case of the standard luminance shown by the broken line in FIG. The visual color reproduction range can be expanded. That is, an image containing a large number of pure colors such as R, G, B, C (cyan), M (magenta), and Y (yellow), that is, an image having high chroma (or a large amount of chromatic color components). By displaying more brightly, it becomes possible to display an image that is perceived more vividly.

  It has been empirically known that when the brightness of a display image increases, it is perceived as being more vivid. In addition, even if the colors have the same chromaticity, a phenomenon in which the perceived saturation changes as the brightness changes is known as the Hunt effect. On the other hand, in an image with low saturation (a small amount of chromatic color component) such as a black and white image, the perceived average luminance level does not change. Therefore, by increasing the luminance of the light source in accordance with the saturation of the image, the luminance difference from the black and white image to the pure color image is expressed more greatly, so that a colorful display image can be obtained.

  FIG. 11 shows the color reproduction range of the display device 100 when the light emitting unit 7 emits light based on the light emission control data c, that is, when the light emitting unit 7 emits light with a luminance lower than the standard. In the display device 100 according to the present embodiment, as shown in FIG. 8, the light emission control data is a value c smaller than the standard value a in the low saturation and low luminance divided portions, and the luminance of the illumination light is Decrease. As a result, as shown by the solid line in FIG. 11, the low-saturation and low-brightness part close to black is displayed darker and the black floats compared to the standard luminance shown by the broken line in FIG. 11. This can be suppressed and the contrast of the display image can be improved.

  FIG. 12 shows a color reproduction range of the display device 100 when the light emitting unit 7 emits light based on the light emission control data d, that is, when the light emitting unit 7 emits light with a brightness brighter than the standard. In the display device 100 according to the present embodiment, as shown in FIG. 8, the light emission control data has a value d larger than the standard value a in the low saturation and high luminance divided portions, and the luminance of the illumination light is high. To rise. As a result, as shown by the solid line in FIG. 12, compared to the standard brightness shown by the broken line in FIG. Contrast can be improved.

According to the first embodiment described above, the following effects (1) to (4) can be obtained.
(1) In the present embodiment, for each divided portion of the light modulator, the saturation of the portion corresponding to the divided portion of the image represented by the image data is determined, and the luminance of the portion is estimated. Based on the saturation determination result and the luminance estimation result, the luminance of the illumination light corresponding to the divided portion is controlled. Therefore, according to the present embodiment, the luminance of the illumination light can be adjusted according to the saturation and luminance of the image for each divided portion, and only based on the saturation (or the amount of chromatic color components). A brighter and higher-contrast display image can be obtained than when the brightness of the entire screen is adjusted. In addition, just by detecting the color component, by performing the processing as described above, it is possible to make the divided part of interest vivid and to control the luminance of the illumination light by estimating the luminance of the image. High contrast can be achieved.

  (2) In one aspect, the brightness of the illumination light corresponding to the divided portion is controlled to become brighter as the saturation of the image corresponding to the divided portion increases. Specifically, for each divided portion, it is determined whether or not the image portion corresponding to the divided portion is a high saturation portion where the saturation is greater than a predetermined level. Compared with the case where the saturation is smaller than the predetermined level, the luminance of the illumination light corresponding to the divided portion is increased. According to this aspect, it is possible to display a portion where the saturation of the image is high, and to display an image that is perceived more vividly.

  In the display device described in Patent Document 1, even when a high saturation portion exists, if the low saturation portion exists widely, the light source may not be controlled with high brightness, and the high saturation portion may not be displayed vividly. . On the other hand, in the display device according to the present embodiment, the luminance of the illumination light corresponding to the high saturation portion can be selectively controlled to be high, and the high saturation portion can be displayed vividly.

  (3) In one aspect, the luminance of the illumination light corresponding to the divided portion is controlled to become darker as the luminance of the image corresponding to the divided portion is lower. Specifically, for each divided portion, it is determined whether or not the image portion corresponding to the divided portion is a low-saturation low-luminance portion whose saturation is lower than a predetermined level and whose luminance is lower than a predetermined level. However, when it is determined that the portion has low saturation and low luminance, the luminance of the illumination light corresponding to the divided portion is smaller than when the saturation is lower than the predetermined level and the luminance is higher than the predetermined level. Lower. According to this aspect, the low-saturation and low-luminance part close to black can be displayed darker, black can be prevented from floating, and the contrast of the display image can be improved.

  In the display device described in Patent Document 1, even when a low saturation and low luminance part exists, when a high saturation part exists widely, the light source is controlled with high luminance according to the high saturation part, and the low saturation and low luminance are obtained. The black portion of the image may float and a high-contrast display image may not be obtained. On the other hand, in the display device according to the present embodiment, the luminance of the illumination light corresponding to the low-saturation and low-luminance portion can be selectively controlled to suppress black floating and display with high contrast. An image can be obtained.

  (4) In one aspect, the luminance of the illumination light corresponding to the divided portion is controlled so as to increase as the luminance of the image corresponding to the divided portion increases. Specifically, for each divided portion, it is determined whether or not the image portion corresponding to the divided portion is a low-saturation high-luminance portion whose saturation is lower than a predetermined level and whose luminance is higher than a predetermined level. However, when it is determined that the portion is a low-saturation high-luminance portion, the luminance of the illumination light corresponding to the divided portion is smaller than when the saturation is lower than a predetermined level and the luminance is lower than the predetermined level. To increase. According to this aspect, the low-saturation and high-luminance part close to white can be displayed brighter, and the contrast of the display image can be improved.

  In the display device described in Patent Document 1, when a low-saturation and high-luminance part is present, the light source is not controlled with high luminance and a high-contrast display image may not be obtained. On the other hand, in the display device according to the present embodiment, the luminance of the illumination light corresponding to the low saturation high luminance portion can be selectively controlled to be high, and a high contrast display image can be obtained.

  In the above description, the configuration in which the saturation determination unit 4 generates the saturation determination data and the luminance estimation data based on the maximum average value, the minimum average value, and the difference value between both average values is exemplified. However, the saturation determination data and the luminance estimation data may be generated by other configurations as follows.

  FIG. 13 is a block diagram illustrating another configuration example of the saturation determination unit 4. Hereinafter, another configuration example of the saturation determination unit 4 will be described with reference to FIG. The saturation determination unit 4 shown in FIG. 13 includes a maximum value detection unit 11, a minimum value detection unit 12, a maximum value frequency distribution information calculation unit 20, a minimum value frequency distribution information calculation unit 21, and a chromatic color component determination threshold storage unit 16. , A low luminance component determination threshold storage unit 17, a high luminance component determination threshold storage unit 18, and a divided partial component determination unit 19.

  The maximum value detection unit 11 receives the image data from the reception unit 2, and for each pixel in the portion corresponding to the divided portion of interest in the image data, the colors of R, G, and B of the sub-pixels constituting the pixel Among the data, the maximum value is output to the maximum frequency distribution information calculation unit 20 as maximum value data. The maximum value frequency distribution information calculation unit 20 calculates the frequency distribution of the maximum value data of the pixels in the portion corresponding to the focused portion of the image data as the maximum value frequency distribution information. The maximum value frequency distribution information is information indicating the appearance frequency for each value (color data value) of the maximum value data. The calculated maximum frequency distribution information is supplied to the divided partial component determination unit 19.

  The minimum value detection unit 12 receives the image data from the reception unit 2, and for each pixel in the portion corresponding to the divided portion of interest in the image data, the R, G, and B colors of the sub-pixels constituting the pixel Of the data, the smallest value is output as minimum value data to the minimum frequency distribution information calculation unit 21. The minimum value frequency distribution information calculation unit 21 calculates the frequency distribution of the minimum value data of the pixels in the portion corresponding to the divided portion of interest in the image data as the minimum value frequency distribution information. The minimum value frequency distribution information is information indicating the appearance frequency for each value (color data value) of the minimum value data. The calculated minimum frequency distribution information is supplied to the divided partial component determination unit 19.

  The divided partial component determination unit 19 includes maximum value frequency distribution information from the maximum value frequency distribution information calculation unit 20, minimum value frequency distribution information from the minimum value frequency distribution information calculation unit 21, and a chromatic color component determination threshold storage unit 16. Based on the chromatic color component determination threshold, the low luminance component determination threshold stored in the low luminance component determination threshold storage unit 17, and the high luminance component determination threshold stored in the high luminance component determination threshold storage unit 18. Thus, the saturation determination data and the luminance estimation data of the divided portion under attention are generated and output.

  FIG. 14 is a flowchart illustrating another example of the saturation determination unit 4. Hereinafter, a processing example of the saturation determination unit 4 illustrated in FIG. 13 will be described with reference to FIG. FIG. 14 particularly shows an example of the processing procedure of the divided partial component determination unit 19 of the saturation determination unit 4 configured as shown in FIG.

  First, the divided part component determination unit 19 receives the maximum value frequency distribution information and the minimum value frequency distribution information of the divided part of interest (ST11).

  Next, the divided part component determination unit 19 calculates the amount (or saturation) of the chromatic color component of the image part corresponding to the divided part from the maximum value frequency distribution information and the minimum value frequency distribution information of the divided part of interest. A value to be expressed is obtained, and by comparing the value with a chromatic color component determination threshold value, it is determined whether or not the image portion corresponding to the divided portion of interest is a high saturation portion (ST12). For example, the divided partial component determination unit 19 calculates the total value of the frequency of color data values greater than or equal to a predetermined value in the maximum value frequency distribution information (that is, the number of data of color data values greater than or equal to the predetermined value) and the predetermined value in the minimum value frequency distribution information. When the absolute value of the difference from the total frequency of the color data values less than the value (that is, the number of data values less than the predetermined value) is obtained and the absolute value of the difference is less than or equal to the chromatic color component determination threshold, It is determined to be a part. Further, for example, the divided partial component determination unit 19 calculates the sum of products of each color data value of the maximum value frequency distribution information and its frequency (data number), and each color data value of the minimum value frequency distribution information and its frequency (data number). When the difference is equal to or greater than the chromatic color component determination threshold, it is determined that the portion is a high saturation portion. In this case, when the maximum value frequency distribution information or the minimum value frequency distribution information includes the color data value “0”, the divided partial component determination unit 19 adds “1” to all the color data values of the frequency distribution information. Then, the determination may be made after conversion to frequency distribution information in which the color data value “0” does not exist. Further, for example, the divided partial component determination unit 19 represents the representative value (average value, mode value, median value, etc.) of the frequency distribution indicated by the maximum value frequency distribution information and the representative of the frequency distribution indicated by the maximum value frequency distribution information. A difference from the value is obtained, and when the difference is greater than or equal to the chromatic color component determination threshold, it is determined that the portion is a high saturation portion.

  When it is determined that the portion is a high saturation portion (ST12: YES), the divided portion component determination unit 19 outputs saturation determination data indicating that the portion is a high saturation portion, and the low saturation and the high luminance even in the low saturation and the low luminance portion. Luminance estimation data indicating that it is not a part is output (ST13).

  On the other hand, when it is determined that the portion is not a high saturation portion (ST12: NO), the divided portion component determining unit 19 represents the luminance of the image portion corresponding to the divided portion from the maximum value frequency distribution information of the divided portion of interest. A value is obtained, and it is determined whether the value is smaller than a low luminance component determination threshold value (ST14). For example, the divided partial component determination unit 19 obtains the minimum value among the color data values whose frequency is 1 or more in the maximum value frequency distribution information, and the minimum value is set as the low luminance component determination threshold value. Is smaller than the low-luminance component determination threshold. Further, for example, the divided partial component determination unit 19 obtains the sum of products of each color data value of the maximum value frequency distribution information and the frequency (data number), and when the total is smaller than the low luminance component determination threshold, Is determined to be smaller than the low luminance component determination threshold. In this case, the low luminance component determination threshold is set by, for example, a product of a certain low luminance data value and the number of data. When the maximum value frequency distribution information includes the color data value “0”, the divided partial component determination unit 19 adds “1” to all the color data values of the frequency distribution information, etc. The determination may be made after conversion to frequency distribution information in which “0” does not exist. In addition, for example, the divided partial component determination unit 19 obtains a representative value (average value, mode value, median value, etc.) of the frequency distribution indicated by the maximum value frequency distribution information, and the representative value is lower than the low luminance component determination threshold value. When the value is small, it is determined that the value representing the luminance is smaller than the low luminance component determination threshold.

  As a result of the determination, if the value representing the luminance is smaller than the low luminance component determination threshold value (ST14: YES), the divided portion component determination unit 19 displays the image portion corresponding to the divided portion of interest as a low saturation, low luminance. The portion is determined as a portion, and saturation determination data and luminance estimation data indicating a low saturation and low luminance portion are output (ST15). Specifically, the divided partial component determination unit 19 outputs saturation determination data indicating a low saturation portion and luminance estimation data indicating a low luminance portion.

  On the other hand, when the value representing luminance is larger than the low-luminance component determination threshold (ST14: NO), the divided portion component determination unit 19 corresponds to the divided portion from the minimum value frequency distribution information of the divided portion of interest. A value representing the luminance of the image portion is obtained, and it is determined whether or not the value is larger than a high luminance component determination threshold (ST16). For example, the divided partial component determination unit 19 obtains the maximum value among color data values whose frequency is 1 or more in the minimum value frequency distribution information, and the color data value in which the maximum value is set as the high luminance component determination threshold value Is greater than the high luminance component determination threshold. Further, for example, the divided partial component determination unit 19 obtains the sum of products of each color data value of the minimum value frequency distribution information and the frequency (data number), and when the total is larger than the high luminance component determination threshold, Is determined to be greater than the high luminance component determination threshold. In this case, the high luminance component determination threshold is set by, for example, a product of a certain high luminance data value and the number of data. Further, when the minimum value frequency distribution information includes the color data value “0”, the divided partial component determination unit 19 adds “1” to all the color data values of the frequency distribution information. The determination may be made after conversion to frequency distribution information in which “0” does not exist. Further, for example, the divided partial component determination unit 19 obtains a representative value (average value, mode value, median value, etc.) of the frequency distribution indicated by the minimum value frequency distribution information, and the representative value is higher than the high luminance component determination threshold value. When the value is larger, it is determined that the value representing the luminance is larger than the high luminance component determination threshold value.

  As a result of the determination, if the value representing the luminance is larger than the high luminance component determination threshold value (ST16: YES), the divided portion component determination unit 19 displays the image portion corresponding to the divided portion of interest as a low saturation high luminance. The portion is determined as a portion, and saturation determination data and luminance estimation data indicating that the portion is a low saturation and high luminance portion are output (ST17). Specifically, the divided partial component determination unit 19 outputs saturation determination data indicating a low saturation portion and luminance estimation data indicating a high luminance portion.

  On the other hand, when the value representing luminance is smaller than the high luminance component determination threshold (ST16: NO), the divided partial component determination unit 19 determines that neither the high saturation portion, the low saturation low luminance portion, nor the low saturation high luminance portion is present. The saturation determination data and luminance estimation data shown are output (ST18). Specifically, the divided part component determination unit 19 performs saturation determination data indicating that the portion is not a high saturation portion (or is a low saturation portion), and is not a low luminance portion or a high luminance portion (or a medium luminance portion). Brightness estimation data indicating that the

  Similar to the case of FIG. 6, the saturation determination unit 4 performs the above-described processing for each of the plurality of divided regions, and generates and outputs the saturation determination data and the luminance estimation data for each divided portion at a predetermined period. . Further, as in the case of FIG. 6, the saturation determination unit 4 adds degree information indicating how much the threshold has been exceeded or how far the threshold has not been reached, in addition to information on whether or not the portion is a chromatic portion or the like. May be included in the saturation determination data and the luminance estimation data. Similarly to the case of FIG. 6, the portion determined as the low saturation portion can be set to be always included in either the low saturation low luminance portion or the low saturation high luminance portion. . The order of the above processes may be changed as appropriate. For example, the order of the determination based on the chromatic color component determination threshold, the determination based on the low luminance component determination threshold, and the determination based on the high luminance component determination threshold may be changed as appropriate.

  FIG. 15 is a block diagram illustrating another configuration example of the saturation determination unit 4. Hereinafter, another configuration example of the saturation determination unit 4 will be described with reference to FIG. 15 includes a maximum value detection unit 11, a minimum value detection unit 12, a maximum value average value calculation unit 13, a minimum value average value calculation unit 14, a subtraction unit 15, and an intermediate average value calculation unit 22. A chromatic color component determination threshold storage unit 16, a low luminance component determination threshold storage unit 17, a high luminance component determination threshold storage unit 18, and a divided partial component determination unit 19.

  The maximum value detection unit 11 receives the image data from the reception unit 2, and for each pixel in the portion corresponding to the divided portion of interest in the image data, the colors of R, G, and B of the sub-pixels constituting the pixel Among the data, the value of the maximum value is output to the maximum value average value calculation unit 13 as maximum value data. The maximum value average value calculation unit 13 calculates the average value of the maximum value data of the pixels in the portion corresponding to the divided portion of interest in the image data as the maximum value average value. The calculated maximum value average value is supplied to the subtraction unit 15 and the intermediate average value calculation unit 22.

  The minimum value detection unit 12 receives the image data from the reception unit 2, and for each pixel in the portion corresponding to the divided portion of interest in the image data, the R, G, and B colors of the sub-pixels constituting the pixel Of the data, the smallest value is output as minimum value data to the minimum value average value calculation unit 14. The minimum value average value calculation unit 14 calculates the average value of the minimum value data of the pixels in the portion corresponding to the divided portion of interest in the image data as the minimum value average value. The calculated minimum average value is supplied to the subtraction unit 15 and the intermediate average value calculation unit 22.

  The subtraction unit 15 calculates a difference value between the maximum value average value and the minimum value average value of the divided portion of interest by subtracting the output of the minimum value average value calculation unit 14 from the output of the maximum value average value calculation unit 13. And output to the divided partial component determination unit 19.

  The intermediate average value calculation unit 22 calculates the average value of the maximum value average value and the minimum value average value of the divided portion under attention as the intermediate average value. The calculated intermediate average value is supplied to the divided partial component determination unit 19.

  The divided partial component determination unit 19 includes a difference value from the subtraction unit 15, an intermediate average value from the intermediate average value calculation unit 22, a chromatic color component determination threshold stored in the chromatic color component determination threshold storage unit 16, and a low Based on the low luminance component determination threshold stored in the luminance component determination threshold storage unit 17 and the high luminance component determination threshold stored in the high luminance component determination threshold storage unit 18, the saturation determination data of the divided portion under attention And luminance estimation data are generated and output.

  FIG. 16 is a flowchart illustrating another example of the saturation determination unit 4. Hereinafter, another processing example of the saturation determination unit 4 will be described with reference to FIG. FIG. 16 particularly shows an example of the processing procedure of the divided partial component determination unit 19 of the saturation determination unit 4 configured as shown in FIG.

  First, the divided part component determination unit 19 calculates a difference value between the maximum average value and the minimum average value of the target divided part, and an intermediate average value that is an average value of the maximum average value and the minimum average value. An input is received (ST21).

  Next, the divided part component determination unit 19 determines whether or not the difference value between the maximum average value and the minimum average value of the divided part of interest is equal to or greater than the chromatic color component determination threshold (ST22).

  When the difference value is equal to or greater than the chromatic color component determination threshold (ST22: YES), the divided portion component determination unit 19 determines the image portion corresponding to the divided portion of interest as the high saturation portion, and is the high saturation portion. Is output, and brightness estimation data indicating that neither low saturation, low brightness part nor low saturation, high brightness part is output (ST23).

  On the other hand, when the difference value is smaller than the chromatic color component determination threshold value (ST22: NO), the divided portion component determination unit 19 determines whether or not the intermediate average value of the divided portion of interest is smaller than the low luminance component determination threshold value. Determine (ST24).

  As a result of the determination, when the intermediate average value is smaller than the low luminance component determination threshold value (ST24: YES), the divided portion component determination unit 19 determines the image portion corresponding to the divided portion of interest as the low saturation low luminance portion. The saturation determination data and the luminance estimation data indicating the low saturation and low luminance portion are output (ST25). Specifically, the divided partial component determination unit 19 outputs saturation determination data indicating a low saturation portion and luminance estimation data indicating a low luminance portion.

  On the other hand, when the intermediate average value is larger than the low luminance component determination threshold value (ST24: NO), the divided portion component determination unit 19 determines whether the intermediate average value of the divided portion of interest is larger than the high luminance component determination threshold value. Is determined (ST26).

  As a result of the determination, when the intermediate average value is larger than the high luminance component determination threshold value (ST26: YES), the divided portion component determination unit 19 determines the image portion corresponding to the divided portion of interest as the low saturation high luminance portion. And saturation determination data and luminance estimation data indicating that the portion is low saturation and high luminance are output (ST27). Specifically, the divided partial component determination unit 19 outputs saturation determination data indicating a low saturation portion and luminance estimation data indicating a high luminance portion.

  On the other hand, when the intermediate average value is smaller than the high luminance component determination threshold value (ST26: NO), the divided partial component determination unit 19 indicates that neither the high saturation portion, the low saturation low luminance portion, nor the low saturation high luminance portion is present. Saturation determination data and luminance estimation data are output (ST28). Specifically, saturation determination data indicating that the portion is not a high saturation portion (or that it is a low saturation portion), and luminance estimation indicating that the portion is neither a low luminance portion nor a high luminance portion (or that it is a medium luminance portion) Output data.

  Similar to the case of FIG. 6, the saturation determination unit 4 performs the above-described processing for each of the plurality of divided regions, and generates and outputs the saturation determination data and the luminance estimation data for each divided portion at a predetermined period. . Further, as in the case of FIG. 6, the saturation determination unit 4 adds degree information indicating how much the threshold has been exceeded or how far the threshold has not been reached, in addition to information on whether or not the portion is a chromatic portion or the like. May be included in the saturation determination data and the luminance estimation data. Similarly to the case of FIG. 6, the portion determined as the low saturation portion can be set to be always included in either the low saturation low luminance portion or the low saturation high luminance portion. . The order of the above processes may be changed as appropriate. For example, the order of the determination based on the chromatic color component determination threshold, the determination based on the low luminance component determination threshold, and the determination based on the high luminance component determination threshold may be changed as appropriate. In step ST24, the divided partial component determination unit 19 determines whether the intermediate average value is smaller than the low luminance component determination threshold value and the difference value between the maximum value average value and the minimum value average value is smaller than the chromatic color component determination threshold value. In step ST26, it is determined whether the intermediate average value is larger than the high luminance component determination threshold value and the difference value between the maximum average value and the minimum average value is smaller than the chromatic color component determination threshold value. Also good. In this case, the divided partial component determination unit 19 proceeds from step ST21 to step ST24. If the determination result in step ST24 is YES, the process proceeds to step ST25. If NO, the process proceeds to step ST26. If the determination result in step ST26 is YES, the process proceeds to step ST27, and if NO, the process proceeds to step ST22. If the determination result of step ST22 is YES, the process proceeds to step ST23, and if NO, the process proceeds to step ST28.

Embodiment 2. FIG.
FIG. 17 is a block diagram illustrating a configuration of a display device 200 including the light emitting device 10 according to the second embodiment. The display device 200 is different from the display device 100 of the first embodiment in the configuration of the control device 8, and the other parts are substantially the same. In the following description, the description of the same parts as those in the first embodiment is omitted or simplified, and the same or corresponding elements as those in the first embodiment are denoted by the same reference numerals.

  In the present embodiment, the control device 8 corresponds to each divided portion so that the difference in luminance of the illumination light between adjacent divided portions among the plurality of divided portions of the light modulation unit 3 is equal to or less than a predetermined level. The brightness of the illumination light to be controlled (specifically, the brightness of the plurality of light emitting units 7) is controlled.

  Specifically, as illustrated in FIG. 17, the control device 8 includes the adjacent limit reference value storage unit 31 and the light emission in addition to the saturation determination unit 4, the light emission control data generation unit 5, and the light emission drive control unit 6. A control data adjustment unit 32 is included.

  The adjacency restriction reference value storage unit 31 stores a preset adjacency restriction reference value. The adjoining restriction reference value is a reference value for adjusting the light emission control data so that the difference in luminance of the illumination light between the adjacent divided portions is equal to or less than a predetermined level. Specifically, the adjoining restriction reference value is a limit value of a difference in luminance of illumination light (or a difference in light emission control data) in which a difference in luminance of illumination light between adjacent divided portions is not visually recognized. For example, the adjacent restriction reference value is obtained when the light emitting unit 7 emits light with different brightness between the adjacent divided units in a state where the light modulating unit 3 displays a uniform image. 3 is an upper limit value of the difference in luminance of illumination light (or difference in light emission control data) in which the luminance difference between the divided parts is not recognized. The adjacent restriction reference value is determined by, for example, the characteristics of the light emitting unit 7 and the characteristics of the light modulation unit 3. When there are a plurality of adjacent portions adjacent to each other, the adjacent restriction reference value for each adjacent portion corresponding to each adjacent portion may be set, or one common adjacent restriction corresponding to the plurality of adjacent portions A reference value may be set.

  The light emission control data adjustment unit 32 adjusts the light emission control data for each divided portion output from the light emission control data generation unit 5 based on the adjacent restriction reference value stored in the adjacent restriction reference value storage unit 31 and adjusts the light emission control data. The subsequent light emission control data is output as light emission control adjustment data. Specifically, the light emission control data adjusting unit 32 emits the light emission control data for each divided portion so that the difference in the light emission control data between the adjacent divided portions is equal to or less than the reference value corresponding to the adjacent restriction reference value. Make adjustments. Here, the adjoining restriction reference value may be data in the same unit as the light emission control data, and the light emission control data adjustment unit 32 sets the light emission control data so that the difference in the light emission control data is equal to or smaller than the adjacency restriction reference value. Adjustments may be made. Alternatively, the adjacent restriction reference value may be a luminance difference value of the light emitting unit 7. In this case, for example, the adjacent restriction reference value is converted into data in units corresponding to the light emission control data in the adjacent restriction reference value storage unit 31 or the light emission control data adjustment unit 32, and the data is used as the reference value.

  The light emission drive control unit 6 generates a light emission drive signal for causing each light emitting unit 7 to emit light based on the light emission control adjustment data for each divided portion from the light emission control data adjusting unit 32, and supplies the light emission drive signal to each light emitting unit 7. Specifically, the light emission drive control unit 6 generates a light emission drive signal for causing the light emitting unit 7 corresponding to the divided part to illuminate according to the light emission control adjustment data of the divided part for each divided part. It outputs to the light emission part 7 corresponding to a division | segmentation part. Thereby, the light emission part 7 corresponding to each division part emits light with the brightness | luminance according to the light emission control adjustment data of each division part.

  FIG. 18 is a flowchart illustrating a processing example of the light emission control data adjustment unit 32 of the light emitting device 10 according to the second embodiment. Hereinafter, a processing example of the light emission control data adjustment unit 32 will be described with reference to FIG.

  First, the light emission control data adjustment unit 32 receives the light emission control data of each of the plurality of divided portions of the light modulation unit 3 (ST31).

  Next, the light emission control data adjustment unit 32 acquires, as an adjacent value, the difference in the light emission control data between the divided parts adjacent to each other in each adjacent part where the divided parts are adjacent to each other (ST32).

  Next, the light emission control data adjustment unit 32 determines whether or not each acquired adjacent value is equal to or less than the adjacent restriction reference value (ST33). If each adjacent value is equal to or smaller than the adjoining restriction reference value (ST33: YES), the light emission control data adjustment unit 32 uses the light emission control data for each divided portion input in step ST31 as it is. To the light emission drive controller 6 (ST36).

  On the other hand, when at least one adjacent value exceeds the adjoining restriction reference value (ST33: NO), the light emission control data adjustment unit 32 adjoins the adjoining portion for which the adjoining value exceeds the adjoining restriction reference value. The light emission control data of the divided part is adjusted so that the adjacent value is equal to or smaller than the adjacent limit reference value (ST34).

  After the adjustment, the light emission control data adjustment unit 32 determines whether or not each adjacent value is equal to or less than the adjacent limit reference value (ST35). Then, if at least one adjacent value exceeds the adjacent restriction reference value (ST35: NO), the light emission control data adjusting unit 32 adjusts the light emission control data again (ST34), and each adjacent value is set to the adjacent restriction reference value. If it is equal to or less than the value (ST35: YES), the adjusted light emission control data is output to the light emission drive control unit 6 as light emission control adjustment data (ST36). That is, the light emission control data adjustment unit 32 repeats the adjustment of the light emission control data until each adjacent value becomes equal to or less than the adjacent limit reference value. In this case, when the adjacent restriction reference value is exceeded at a plurality of adjacent parts for a certain divided part, for example, the light emission control data adjustment unit 32 gives priority to the adjacent part that is the largest and exceeds the adjacent restriction reference value. Adjust the data.

  In addition, said process is an example and may be changed suitably. For example, the adjacent restriction reference value may be a value that changes according to the image components of the divided portions adjacent to each other. For example, since the sensitivity of human eyes increases as the screen becomes darker, the adjacent restriction reference value corresponding to the adjacent portion between the dark divided portions is set small, and the adjacent restriction reference value corresponding to the adjacent portion between the bright divided portions is set large. For example, there may be a plurality of adjacent restriction reference values according to conditions.

According to the second embodiment described above, the following effect (5) can be obtained in addition to the effect of the first embodiment.
(5) In the present embodiment, the luminance of the illumination light corresponding to each divided portion (specifically, so that the difference in luminance between the divided portions adjacent to each other among the plurality of divided portions is a predetermined level or less. Specifically, the luminance of a plurality of light emitting units is controlled. For this reason, according to this Embodiment, the difference in the brightness | luminance of the illumination light between the division parts adjacent to each other can be suppressed to a predetermined level or less, and the luminance difference between the divided parts can be made difficult to be visually recognized. .

  In the first and second embodiments described above, the function of the control device 8 may be realized only by hardware resources such as an electronic circuit, or may be realized by cooperation of hardware resources and software. When realized by the cooperation of hardware resources and software, the function of the control device 8 is realized, for example, by a control program being executed by a computer. More specifically, the function of the control device 8 is executed by a central processing unit (CPU) by reading a control program recorded in a recording medium such as a ROM (Read Only Memory) into the main storage device. It is realized by doing. The control program may be provided by being recorded on a computer-readable recording medium such as an optical disk, or may be provided via a communication line such as the Internet.

  In addition, this invention is not limited to the said embodiment, In the range which does not deviate from the summary of this invention, it can implement with a various aspect.

  DESCRIPTION OF SYMBOLS 1 Input terminal, 2 Receiving part, 3 Light modulation part, 4 Saturation determination part with a luminance estimation function, 5 Light emission control data generation part, 6 Light emission drive control part, 7 Light emission part, 8 Control apparatus, 10 Light emission apparatus, 11 Maximum Value detection unit, 12 Minimum value detection unit, 13 Maximum value average value calculation unit, 14 Minimum value average value calculation unit, 15 Subtraction unit, 16 Chromatic color component determination threshold storage unit, 17 Low luminance component determination threshold storage unit, 18 High Luminance component determination threshold storage unit, 19 divided partial component determination unit, 20 maximum value frequency distribution information calculation unit, 21 minimum value frequency distribution information calculation unit, 22 intermediate average value calculation unit, 31 adjacent restriction reference value storage unit, 32 light emission control Data adjustment unit, 100,200 display device.

Claims (13)

At least one is arranged for each of the plurality of divided portions obtained by dividing the light modulation means for displaying the image by modulating the illumination light based on the image data, and emits the illumination light irradiated to the light modulation means A plurality of light emitting means;
Saturation determination means with a luminance estimation function for determining the saturation of the portion corresponding to the divided portion of the image represented by the image data for each divided portion, and estimating the luminance of the portion;
Control means for controlling the luminance of the light emitting means corresponding to the divided portion based on the determination result of the saturation and the estimation result of the luminance for each divided portion;
A light emitting device comprising: For each of the divided portions, the saturation determination unit with a luminance estimation function is a low saturation low image portion corresponding to the divided portion in which the saturation is lower than a predetermined level and the luminance is lower than the predetermined level. It has a function to determine whether it is a luminance part,
The control means, for each of the divided portions, when it is determined that the image portion corresponding to the divided portion is the low saturation low luminance portion, the saturation is smaller than the predetermined level, and the Control is performed such that the luminance of the light emitting means corresponding to the divided portion is lower than when the luminance is greater than the predetermined level.
The light-emitting device according to claim 1. For each of the divided portions, the saturation determination unit with a luminance estimation function has a low saturation high level in which the image portion corresponding to the divided portion has a saturation lower than a predetermined level and the luminance higher than a predetermined level. It has a function to determine whether it is a luminance part,
The control means, for each of the divided portions, when it is determined that the image portion corresponding to the divided portion is the low saturation high luminance portion, the saturation is smaller than the predetermined level, and the Control is performed so that the luminance of the light emitting means corresponding to the divided portion is higher than when the luminance is lower than the predetermined level.
The light-emitting device according to claim 1 or 2.   The control means controls the luminance of the plurality of light emitting means so that a difference in luminance of the illumination light between adjacent divided portions among the plurality of divided portions becomes a predetermined level or less. The light emitting device according to any one of claims 1 to 3. The control means includes
Light emission control data generation means for generating light emission control data for controlling the luminance of the light emission means corresponding to the divided portion based on the determination result of the saturation and the estimation result of the luminance for each divided portion. When,
A light emission control data adjusting means for adjusting the light emission control data for each of the divided parts so that a difference between the light emission control data between the divided parts adjacent to each other among the plurality of divided parts is a predetermined reference value or less;
The light-emitting device according to claim 1, wherein The light emitting device according to any one of claims 1 to 5,
The light modulation means for displaying an image by modulating the illumination light from the light emitting device;
A display device comprising: A control device used in a display device including a light modulation unit that modulates illumination light based on image data to display an image,
For each of a plurality of divided portions obtained by dividing the light modulation means, with a luminance estimation function for determining the saturation of the portion corresponding to the divided portion of the image represented by the image data and estimating the luminance of the portion Saturation determination means;
Control means for controlling the luminance of the illumination light corresponding to the divided portion based on the determination result of the saturation and the estimation result of the luminance for each divided portion;
A control device comprising: At least one light modulating unit that modulates illumination light based on image data to display an image and each of a plurality of divided portions obtained by dividing the light modulating unit is disposed and irradiated to the light modulating unit. A control method used for a display device comprising a plurality of light emitting means for emitting the illumination light,
A determination step for determining the saturation of a portion corresponding to the divided portion of the image represented by the image data for each divided portion and estimating the luminance of the portion;
A control step for controlling the luminance of the light emitting means corresponding to the divided portion based on the determination result of the saturation and the estimation result of the luminance for each divided portion;
A control method characterized by comprising: In the determination step, for each of the divided portions, whether the image portion corresponding to the divided portion is a low-saturation low-luminance portion in which the saturation is lower than a predetermined level and the luminance is lower than the predetermined level. Determine whether
In the control step, for each of the divided portions, when it is determined that the image portion corresponding to the divided portion is the low saturation low luminance portion, the saturation is smaller than the predetermined level, and the Control is performed such that the luminance of the light emitting means corresponding to the divided portion is lower than when the luminance is greater than the predetermined level.
The control method according to claim 8. In the determination step, for each of the divided portions, whether the image portion corresponding to the divided portion is a low-saturation high-luminance portion in which the saturation is smaller than a predetermined level and the luminance is larger than a predetermined level. Determine whether
In the control step, for each of the divided portions, when it is determined that the image portion corresponding to the divided portion is the low saturation high luminance portion, the saturation is smaller than the predetermined level, and the Control is performed so that the luminance of the light emitting means corresponding to the divided portion is higher than when the luminance is lower than the predetermined level.
10. The control method according to claim 8 or 9, wherein:   In the control step, the luminance of the plurality of light emitting means is controlled such that a difference in luminance of the illumination light between adjacent divided portions among the plurality of divided portions is equal to or lower than a predetermined level. The control method according to any one of claims 8 to 10. The control step includes
A light emission control data generating step for generating light emission control data for controlling the luminance of the light emitting means corresponding to the divided portion based on the determination result of the saturation and the estimation result of the luminance for each divided portion. When,
A light emission control data adjustment step for adjusting the light emission control data for each of the divided parts such that a difference between the light emission control data between adjacent divided parts among the plurality of divided parts is equal to or less than a predetermined reference value;
The control method according to claim 8, wherein the control method comprises: At least one light modulating unit that modulates illumination light based on image data to display an image and each of a plurality of divided portions obtained by dividing the light modulating unit is disposed and irradiated to the light modulating unit. A control program used in a display device comprising a plurality of light emitting means for emitting the illumination light,
A determination step for determining the saturation of a portion corresponding to the divided portion of the image represented by the image data for each divided portion and estimating the luminance of the portion;
A control step for controlling the luminance of the light emitting means corresponding to the divided portion based on the detection result of the saturation and the estimated result of the luminance for each divided portion;
A control program that causes a computer to execute.

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