JP2019215507A - Display unit and method for controlling the same - Google Patents

Abstract

To provide a technology that can reduce power consumption and display an image more suitable to a user.SOLUTION: A display unit of the present invention comprises: display means that displays, on a screen, an image based on input image data; and control means that performs control of decreasing, compared with an upper limit of a display luminance range of a first area in the screen of the display means, an upper limit of a display luminance range of a second area other than the first area in the screen of the display means, so that the power consumption of the display means becomes equal to or less than a predetermined power consumption.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a display device and a control method thereof.

  In a display device (HDR (High Dynamic Range) monitor) compatible with high luminance display, an upper limit value (peak luminance) of display luminance may be controlled in order to reduce power consumption of the display device (loading control). For example, when the average luminance of the display image is high, control is performed to reduce the peak luminance, thereby reducing the power consumption of the display device.

  By reducing the upper limit of the display luminance, the display image is displayed dark overall. Even if the user performs the brightness adjustment processing for increasing the brightness of the display image, the intended brightness adjustment processing may not be realized due to the above-described processing for reducing the upper limit of the display brightness. In particular, in a brightness adjustment process for a part of a display image, an intended adjustment result cannot be obtained.

  The image display control device described in Patent Literature 1 improves the visibility of a region of interest by reducing luminance values of an image displayed on the image display device other than the region of interest.

JP-A-2017-90595

  However, according to the technique disclosed in Patent Document 1, when power consumption cannot be sufficiently reduced even if the display luminance other than the region of interest is reduced, loading control is further performed to display a display image at a luminance desired by the user. May not be possible.

  An object of the present invention is to provide a technique capable of reducing power consumption and displaying an image more suitable for a user.

A first aspect of the present invention provides:
Display means for displaying an image based on the input image data on a screen;
It is not the first area of the screen of the display means than the upper limit of the display luminance range of the first area of the screen of the display means so that the power consumption of the display means is equal to or less than a predetermined power consumption. Control means for performing control to lower the upper limit value of the display luminance range of the second area;
A display device comprising:

A second aspect of the present invention provides:
A display step of displaying an image based on the input image data on a screen of the display means,
It is not the first area of the screen of the display means than the upper limit of the display luminance range of the first area of the screen of the display means so that the power consumption of the display means is equal to or less than a predetermined power consumption. A control step of performing control to lower the upper limit value of the display luminance range of the second area;
A control method for a display device, comprising:

A third aspect of the present invention is a program for causing a computer to function as each unit of the above-described display device. A fourth aspect of the present invention is a computer-readable storage medium storing a program for causing a computer to function as each unit of the above-described display device.

  According to the present invention, it is possible to reduce power consumption and display an image more suitable for a user.

FIG. 2 is a block diagram illustrating a configuration example of a display device according to the first embodiment. FIG. 4 is a schematic diagram illustrating an example of a plurality of BL control regions according to Embodiments 1 to 3. FIG. 4 is a schematic diagram illustrating an example of table data according to the first to third embodiments. FIG. 4 is a schematic diagram illustrating an example of an input image according to the first embodiment. FIG. 4 is a schematic diagram illustrating an example of a display image according to the first embodiment. FIG. 9 is a block diagram illustrating a configuration example of a display device according to a second embodiment. FIG. 9 is a schematic diagram illustrating an example of an input image according to a second embodiment. FIG. 14 is a schematic diagram illustrating an example of a display image according to the second embodiment. FIG. 13 is a block diagram illustrating a configuration example of a display device according to a third embodiment. FIG. 14 is a schematic diagram illustrating an example of an input image according to a third embodiment. FIG. 13 is a schematic diagram illustrating an example of a display image according to a third embodiment. FIG. 14 is a block diagram illustrating a configuration example of a display device according to a fourth embodiment. FIG. 14 is a block diagram illustrating a configuration example of a display device according to a fifth embodiment. FIG. 19 is a schematic diagram illustrating an example of input image data and the like according to a fifth embodiment. FIG. 14 is a schematic diagram illustrating an example of a designated area and the like according to a fifth embodiment. FIG. 14 is a schematic diagram illustrating an example of light emission luminance of each light source after correction according to the fifth embodiment. 15 is a flowchart illustrating an example of a control flow of light emission luminance according to the fifth embodiment. It is a schematic diagram which shows an example of the light emission brightness | luminance of each light source concerning a comparative example. FIG. 14 is a schematic diagram illustrating an example of a display image according to a fifth embodiment. FIG. 19 is a block diagram illustrating a configuration example of a display device according to a sixth embodiment. FIG. 19 is a schematic diagram illustrating an example of input image data and composite image data according to a sixth embodiment.

<Example 1>
Hereinafter, Embodiment 1 of the present invention will be described.
[Configuration of Display Device]
FIG. 1 is a block diagram illustrating a configuration example of the display device according to the present embodiment. The display device according to the present embodiment includes a display panel 10, a light emitting unit 20, and a control unit 100. The control unit 100 includes an input unit 101, an area setting unit 102, a memory 103, a pixel value conversion unit 104, an in-area power calculation unit 105, an out-of-area power calculation unit 106, an image processing unit 107, and a light emission control unit 108. . The memory 103, the pixel value conversion unit 104, the in-region power calculation unit 105, the out-of-region power calculation unit 106, the image processing unit 107, and the light emission control unit 108 are controlled by electronic circuits mounted on a control circuit board of the display device. Assume that the function is executed.

  An image based on input image data (image data input to the display device) is displayed on the screen by the display panel 10 and the light emitting unit 20.

  The display panel 10 is a transmissive display panel that displays an image on a screen by transmitting light emitted from the light emitting unit 20 based on input image data. For example, the display panel 10 is a liquid crystal panel, a MEMS (Micro Electro Mechanical System) shutter type display panel, or the like.

  The light emitting section 20 has a plurality of light source sections. For example, when the display device is a liquid crystal display device, the light emitting unit 20 is called a “backlight unit” or the like. Each light source unit has one or more light emitting elements. The light emitting element is an LED (light emitting diode), an organic EL (Electro-Luminescence) element, a laser light source, a cold cathode tube, or the like. In the present embodiment, the plurality of light source units are respectively associated with the plurality of BL control areas on the screen. Each BL control area is a part of the screen. FIG. 2 is a schematic diagram illustrating an example of a plurality of BL control areas. In the example of FIG. 2, the plurality of BL control areas are a plurality of divided areas constituting a screen. Specifically, the plurality of BL control areas are 20 divided areas (rectangular areas) arranged in a matrix of 4 rows and 5 columns. When the light emission luminance of the light source unit changes, the luminance of light emitted to the BL control area corresponding to the light source unit changes.

  The BL control area is not limited to a divided area obtained by dividing a screen. The BL control region may be separated from another BL control region, or at least a part of the BL control region may overlap at least a part of another BL control region. The correspondence between the BL control area and the light source unit need not be a one-to-one correspondence. For example, two or more light source units may be associated with one BL control area. The arrangement of the BL control regions, the number of BL control regions, the shape of the BL control regions, and the like are not particularly limited. For example, a plurality of BL control regions may be arranged in a zigzag pattern, and the number of BL control regions may be more or less than 20. The shape of the BL control region may be a triangle, a hexagon, a circle, or the like. Similarly, the arrangement of the light source units and the number of light source units are not particularly limited.

  The input unit 101 is an interface for inputting input image data. It is assumed that the input image data is input from an output device external to the display device. The input image data may be input to the input unit 101 from a storage medium (not shown) of the display device.

  The area setting unit 102 sets a target area in the screen. As will be described later, the target area is an area within the screen for controlling the power consumption and suppressing the reduction of the peak luminance. An area that is not the target area in the screen is defined as a non-target area. The region setting unit 102 sets a target region on the screen by operating the operation unit such as a GUI (not shown) by the user. The region setting unit 102 outputs information (region information) for specifying the position of the target region on the screen to the in-region power calculation unit 105, the out-of-region power calculation unit 106, and the image processing unit 107. The target region is, for example, a region of interest in which the user is interested, a region of interest in which the user pays attention, and the like.

  Note that only the non-target area may be specified by the user, or both the target area and the non-target area may be specified by the user. Region information indicating only the non-target region may be input to the display device, or region information indicating both the target region and the non-target region may be input to the display device. The target region and the non-target region may not be determined and set according to the user operation, but may be automatically determined and set by the display device. For example, an area where a predetermined object (sun, star, person, vehicle, etc.) is displayed may be automatically determined as a target area. A predetermined area (such as the center of the screen) may be used as the target area.

  The user can designate an arbitrary area in the screen as a target area. In addition, in order to facilitate the processing described below, it is also possible to specify an area including the BL control area as the target area.

The memory 103 stores table data indicating the correspondence between the light emission luminance of the light source unit and the power consumption of the light source unit. FIG. 3 is a schematic diagram showing an example of table data recorded in the memory 103. In this embodiment, the light emission luminance of each light source unit is individually controlled based on the image data. In the table data of FIG. 3, the luminance value of the image data is shown instead of the light emission luminance of the light source unit. In this embodiment, the light emission luminance of the light source unit is controlled to be higher as the luminance value of the image data is larger. The higher the light emission luminance of the light source unit, the higher the power consumption of the light source unit. Therefore, in the table data of FIG. 3, the larger the luminance value of the image data, the higher the power consumption of the light source unit.

  In the table data, information different from the luminance value of the image data may be indicated as information corresponding to the light emission luminance of the light source unit. For example, the light emission luminance of the light source unit, the BL control value for controlling the light emission luminance of the light source unit, the pixel value of the image data, other gradation values (R value, G value, B value, etc.) of the image data, A histogram of pixel values, a histogram of gradation values of image data, and the like may be shown. Instead of the table data, a function indicating the correspondence between the light emission luminance of the light source unit and the power consumption of the light source unit may be prepared.

The pixel value conversion unit 104 converts each pixel value of the input image data into a luminance value Y, and outputs each luminance value Y to the in-region power calculation unit 105 and the out-of-region power calculation unit 106. For example, when the pixel value of the input image data is RGB value (R value, G value, B value) = (R, G, B), the pixel value conversion unit 104 uses the following equation 1 to calculate the luminance. Calculate the value Y. In Equation 1, “α”, “β”, and “γ” are predetermined coefficients (luminance conversion coefficients) for converting RGB values into Y values. Note that the pixel values of the input image data are not limited to the RGB values. For example, the pixel values of the input image data may be YCbCr values. In that case, the pixel value conversion unit 104 may acquire the Y value in the YCbCr value as the luminance value Y.

Y = α × R + β × G + γ × B (Equation 1)

  The intra-region power calculation unit 105 determines a light source unit corresponding to the target region based on the region information. The light source unit corresponding to the target region is a light source unit corresponding to the BL control region including at least a part of the target region. The light source unit corresponding to the BL control region that does not include the non-target region may be set as the light source unit corresponding to the target region. Then, the intra-region power calculation unit 105 calculates the total power consumption WIS of all the light source units corresponding to the target region by using the respective brightness values Y output from the pixel value conversion unit 104 and the table data recorded in the memory 103. Calculated based on After that, the intra-region power calculation unit 105 outputs the total power consumption WIS to the image processing unit 107. The total power consumption WIS is the power consumption when the image processing of the image processing unit 107 is not performed.

  The out-of-region power calculation unit 106 determines a light source unit corresponding to the non-target region based on the region information. The light source unit corresponding to the non-target region is a light source unit other than the light source unit corresponding to the target region, and is, for example, a light source unit corresponding to the BL control region not including the target region. The light source unit corresponding to the non-target region includes a light source unit corresponding to a BL control region including at least a part of the non-target region, a light source unit corresponding to a BL control region including only the non-target region, and the like. Is also good. Then, the out-of-region power calculation unit 106 calculates the total power consumption WOS of all the light source units corresponding to the non-target region, the respective luminance values Y output from the pixel value conversion unit 104, and the table data recorded in the memory 103. Is calculated based on After that, the out-of-region power calculation unit 106 outputs the total power consumption WOS to the image processing unit 107. The total power consumption WOS is the power consumption when the image processing of the image processing unit 107 is not performed.

  The method of calculating the total power consumption WIS and WOS is not particularly limited. For example, instead of the luminance value Y, the light emission luminance of the light source unit, the BL control value, the pixel value of the image data, other gradation values (R value, G value, B value, etc.) of the image data, the pixels of the image data A histogram of values, a histogram of gradation values of image data, and the like may be used.

The image processing unit 107 sets the upper limit of the display brightness range (the range of brightness that can be displayed on the screen) of the target area so that the power consumption of the display unit (specifically, the light emitting unit 20) is equal to or less than the predetermined power consumption. Control is performed so that the upper limit value of the display luminance range of the non-target area is lower than the value. The upper limit of the display luminance range is, for example, the display luminance (luminance on the screen) when the white area of the input image data is displayed on the display unit (specifically, the display panel 10). In the present embodiment, the image processing unit 107 converts the portion of the input image data corresponding to the non-target region so that the power consumption of the light emitting unit 20 is equal to or less than the predetermined power consumption without changing the display luminance of the target region. To process. Specifically, the image processing unit 107 reduces (corrects) the pixel value of a portion of the input image data corresponding to the non-target region, thereby reducing the display luminance of the non-target region. Thereby, corrected image data that is image data after image processing (reduction of pixel values corresponding to the non-target area) is generated. The portion of the input image data corresponding to the non-target region can be said to be the portion of the input image data displayed in the non-target region. The image processing unit 107 reduces the pixel value of the portion of the input image data corresponding to the non-target area based on the total power consumption WIS, WOS and the table data recorded in the memory 103. The image processing unit 107 outputs the corrected image data to the light emission control unit 108. Note that the gradation values used in the image processing are not limited to the R value, the G value, and the B value. For example, luminance values may be used for image processing.

  The light emission control unit 108 controls the light emission luminance of each light source unit based on the brightness of the portion of the input image data corresponding to each light source unit. The light emission control unit 108 controls the light emission luminance of the light source unit corresponding to the non-target area so that the power consumption of the display unit (specifically, the light emitting unit 20) is equal to or less than the predetermined power consumption. In this embodiment, the light emission control unit 108 individually controls the light emission luminance of each of the plurality of light source units included in the light emitting unit 20 based on the corrected image data output from the image processing unit 107. Specifically, the light emission control unit 108 determines the BL control value of each light source unit based on the image data output from the image processing unit 107. Then, the light emission control unit 108 outputs the BL control value of each light source unit to the light emitting unit 20. Each light source unit emits light at a light emission luminance corresponding to the corresponding BL control value. As a result, the light emission luminance of the light source unit corresponding to the non-target area is reduced (controlled) such that the power consumption of the light emitting unit 20 is equal to or less than the predetermined power consumption without changing the luminance of the target area.

  In the present embodiment, for each of the plurality of light source units, the light emission control unit 108 calculates the average pixel value (the average value of the RGB values) of the BL control area corresponding to the plurality of light source units in the image output from the image processing unit 107. Calculate based on data. Then, for each of the plurality of light source units, the light emission control unit 108 determines a BL control value according to the average pixel value calculated for the light source unit. The BL control value is determined such that the larger the average pixel value, the higher the light emission luminance of the light source unit is controlled.

  The method for determining the light emission luminance (BL control value) of the light source unit is not limited to the above method. For example, a representative value (maximum value, minimum value, mode value, intermediate value, etc.) different from the average value may be used. Other tone values, such as luminance values, may be used. The light emission luminance of the light source unit may be controlled based on a histogram of pixel values and gradation values. The upper limit of the display luminance range of the non-target area may be lower than the upper limit of the display luminance range of the target area so that the power consumption of the display unit (specifically, the light emitting unit 20) is equal to or less than the predetermined power consumption. For example, the light emission luminance of each light source unit may be determined without being based on the corrected image data. For example, the light emission luminance (temporary light emission luminance) of each light source unit is determined according to the input image data, and the provisional light emission luminance determined for the light source unit corresponding to the non-target area is corrected. The light emission luminance may be determined. Specifically, the light emission luminance of each light source unit is determined by multiplying the PWM control value (duty ratio corresponding to the provisional light emission luminance) of each light source unit determined according to the input image data by a coefficient. Good. As the coefficient by which the PWM control value is multiplied, for example, a value substantially equal to a value obtained by dividing predetermined power consumption by total power consumption WS described later is used. In this case, generation of corrected image data is not required.

[Processing of In-Region Power Calculation Unit 105]
A specific example of the process of the intra-region power calculation unit 105 will be described.

(Step 1-1)
The intra-region power calculation unit 105 determines (identifies) a light source unit corresponding to the target region based on the region information.

(Step 1-2)
The intra-region power calculation unit 105 determines the average luminance value YAG (the luminance value Y of the luminance value Y) of the BL control region corresponding to the light source unit identified in step 1-1 based on the luminance values Y output from the pixel value conversion unit 104. Average). When a plurality of light source units are specified in step 1-1, the process of step 1-2 is performed for each of the specified plurality of light source units.

(Step 1-3)
The intra-area power calculation unit 105 acquires the power consumption WI corresponding to the average luminance value YAG calculated in step 1-2 from the table data recorded in the memory 103. If a plurality of light source units are specified in step 1-1, the process of step 1-3 is performed for each of the specified plurality of light source units.

(Step 1-4)
The intra-region power calculation unit 105 calculates the sum of all the power consumption WI acquired in step 1-3 as the total power consumption WIS, and outputs the total power consumption WIS to the image processing unit 107.

[Process of Out-of-Region Power Calculation Unit 106]
A specific example of the process of the out-of-region power calculation unit 106 will be described.

(Step 2-1)
The out-of-region power calculation unit 106 determines (specifies) the light source unit corresponding to the non-target region based on the region information.

(Step 2-2)
The out-of-region power calculation unit 106 calculates an average brightness value YAG of the BL control region corresponding to the light source unit specified in step 2-1 based on each brightness value Y output from the pixel value conversion unit 104. If a plurality of light source units are specified in step 2-1, the process of step 2-2 is performed for each of the specified plurality of light source units.

(Step 2-3)
The out-of-region power calculation unit 106 obtains the power consumption WO corresponding to the average luminance value YAG calculated in step 2-2 from the table data recorded in the memory 103. If a plurality of light source units are specified in step 2-1, the process of step 2-3 is performed for each of the specified plurality of light source units.

(Step 2-4)
The out-of-region power calculation unit 106 calculates the sum of all the power consumptions WO acquired in step 2-3 as the total power consumption WOS, and outputs the total power consumption WOS to the image processing unit 107.

[Processing of Image Processing Unit 107]
A specific example of the processing of the image processing unit 107 will be described. Here, among a plurality of RGB values (R value, G value, B value) before image processing, the RGB value corresponding to the target region is described as “RGB value (Rpi, Gpi, Bpi)”, and the non-target region is described. Is described as “RGB value (Rpo, Gpo, Bpo)”. Then, among the plurality of RGB values after the image processing, the RGB value corresponding to the target area is described as “RGB value (Rqi, Gqi, Bqi)”, and the RGB value corresponding to the non-target area is described as “RGB value (Rqo , Gqo, Bqo). " Further, the number of light source units corresponding to the target region is described as “SI”, and the number of light source units corresponding to the non-target region is described as “SO”. Then, the threshold value of the power consumption (predetermined power consumption) is described as “THW”. The threshold value THW may be a predetermined fixed value or a value that can be changed by the user.

(Step 3-1)
The image processing unit 107 calculates the sum of the power information WIS and the power information WOS as the total power consumption WS of all the light source units included in the light emitting unit 20. The total power consumption WS is the power consumption when an image is displayed on the display unit based on the input image data. In the present embodiment, the total power consumption WS is a value obtained when each light source unit is controlled to emit light at the provisional light emission luminance of each light source unit set based on the brightness of the portion of the input image data corresponding to each light source unit. Power consumption. Specifically, the total power consumption WS is the power consumption when the image processing of the image processing unit 107 is not performed. In the present embodiment, the light emission luminance of each light source unit is corrected based on the total power consumption WS and the threshold value THW. Specifically, the corrected image data is generated based on the total power consumption WS and the threshold value THW.

(Step 3-2)
If the total power consumption WS calculated in step 3-1 is equal to or smaller than the threshold value THW, the image processing unit 107 calculates the RGB values after image processing (the RGB values of the corrected image data) according to the following equations (2) and (3). Is calculated to generate corrected image data. That is, when the total power consumption WS is equal to or less than the threshold value THW, the RGB values do not change before and after the image processing, and the same corrected image data as the input image data is generated.

(Rqi, Gqi, Bqi) = (Rpi, Gpi, Bpi) (Equation 2)
(Rqo, Gqo, Bqo) = (Rpo, Gpo, Bpo) (Equation 3)

If the total power consumption WS calculated in step 3-1 is larger than the threshold value THW, the image processing unit 107 calculates the RGB values after image processing according to the following equations 4 to 6, thereby obtaining the corrected image. Generate data. In Equation 6, “K (ε)” is the average luminance value YAG associated with the power consumption ε in the table data recorded in the memory 103. Note that K (ε) may be an average luminance value YAG corresponding to power consumption equal to or lower than power consumption ε. K (ε) may be an average luminance value YAG corresponding to power consumption (ε−Δε) obtained by subtracting a predetermined margin (Δε) from power consumption ε. However, it is assumed that the gradation value K (ε) is a value of 0 or more. The number of bits of the gradation values such as the R value, the G value, the B value, and the luminance value Y is not particularly limited, but in the present embodiment, these gradation values are 8-bit values (0 to 255). According to Equation 6, a plurality of gradation values corresponding to the non-target region are reduced at a common reduction rate (K (ε) / 255).

(Rqi, Gqi, Bqi) = (Rpi, Gpi, Bpi) (Equation 4)
ε = (WOS− (WS−THW)) / SO (Equation 5)
(Rqo, Gqo, Bqo) = (Rpo × (K (ε) / 255),
Gpo × (K (ε) / 255),
Bpo × (K (ε) / 255))
... (Equation 6)

[display]
A specific example of display on the display device according to the present embodiment will be described.

  FIGS. 4A and 4B are schematic diagrams illustrating an example of an image (input image) represented by input image data. 4A and 4B, a round object 402 is drawn on a background 401, and a target area 403 including an area where the round object 402 is displayed is designated. Here, an example in which the user issues an instruction to increase the luminance of the target area 403 will be described. When an instruction to increase the luminance of the target area 403 is issued, the input image data is updated so that the luminance of the target area 403 is increased according to the instruction. FIG. 4A shows the input image before updating, and FIG. 4B shows the input image after updating.

  FIG. 5 is a schematic diagram illustrating an example of an image (display image) displayed on the display device. FIG. 5 shows that the luminance of the target region 403 is increased from the luminance of FIG. 4A in accordance with the instruction from the user, and the luminance of the target region 403 is equal to the luminance of FIG. Then, it can also be seen that the brightness of the area other than the target area 403 is reduced from the brightness of FIGS. 4A and 4B so that the total power consumption WS is equal to or less than the threshold value THW.

  As described above, according to the present embodiment, the upper limit of the display luminance range of the non-target region is set to be smaller than the upper limit of the display luminance range of the target region so that the power consumption of the display unit is equal to or less than the predetermined power consumption. Control for lowering the value is performed. Thereby, it is possible to reduce power consumption and display an image more suitable for the user. Specifically, in the image quality adjustment (such as brightness adjustment) of the target area, an intended adjustment result can be obtained.

  Although the example in which the power consumption WI and WO are determined according to the average luminance value YAG has been described, the method of determining the power consumption is not particularly limited. The above method of determining the power consumptions WI and WO according to the average luminance value YAG is a method based on the control of the light emission luminance of the light source unit according to the average pixel value. In order to determine the power consumption with high accuracy, it is preferable to appropriately determine the method of determining the power consumption based on the method of controlling the light emission luminance of the light source unit.

  Although the example in which the plurality of gradation values corresponding to the non-target region are corrected by the common coefficient (decrease rate) has been described, if the total power consumption WS becomes equal to or less than the threshold THW, the gradation value corresponding to the non-target region Is not particularly limited. The reduction rate may not be common among a plurality of gradation values corresponding to the non-target area. Among a plurality of gradation values corresponding to the non-target region, a gradation value larger than a gradation value K (ε) at which the total power consumption WS is equal to or less than the threshold value THW is a gradation value equal to or smaller than the gradation value K (ε). It may be reduced to a value. Specifically, among a plurality of gradation values corresponding to the non-target region, a gradation value larger than the gradation value K (ε) may be replaced with the gradation value K (ε). According to this method, the size of the region where the luminance is reduced can be reduced. Further, it is possible to eliminate a change in visibility in a region where the gradation value before the image processing is equal to or smaller than the gradation value K (ε).

<Example 2>
Hereinafter, a second embodiment of the present invention will be described. In the first embodiment, the example in which the luminance of the non-target region is reduced has been described. However, when the target area is large, the power consumption of the display unit may not be less than the threshold even if the luminance of the non-target area is reduced. In this embodiment, an example in which such a problem can be solved will be described. In the following, different points (configuration and processing) from the first embodiment will be described in detail, and description of the same points as the first embodiment will be omitted.

[Configuration of Display Device]
FIG. 6 is a block diagram illustrating a configuration example of the display device according to the present embodiment. 6, the same functional units as in the first embodiment (FIG. 1) are denoted by the same reference numerals as in the first embodiment.

The image processing unit 601 performs the same processing as the image processing unit 107 of the first embodiment. Further, the image processing unit 601 performs control so that the upper limit of the display luminance range of a part of the target area is lower than the upper limit of the display luminance range of another part of the target area. This control determines the luminance (pixel value) of the non-target area.
If the power consumption of the light emitting unit 20 does not become equal to or less than the threshold value even if the power consumption is reduced, the power consumption is performed to make the power consumption equal to or less than the threshold value. The central part of the target area often has higher user attention and interest than the edge part of the target area. Therefore, in the present embodiment, the image processing unit 601 performs control so that the upper limit of the display luminance range at the edge of the target area is lower than the upper limit of the display luminance range at the center of the target area. Specifically, the image processing unit 601 determines the brightness (pixel value) of the edge portion of the target region so that the power consumption is equal to or less than the threshold value without changing the brightness (pixel value) of the central portion of the target region. Reduce. The edge portion of the target region is, for example, a region of a predetermined number of pixels from the edge of the target region.

  For example, when the target area is set over a plurality of BL control areas, the pixel value of the portion of the input image data displayed in the BL control area corresponding to the edge of the target area is changed to another BL control area of the target area. Of the input image data displayed on the screen. Thus, the power consumption of the target area is reduced, and the power consumption of the entire display device is reduced.

[Processing of Image Processing Unit 601]
A specific example of the processing of the image processing unit 601 will be described. Here, among a plurality of RGB values (R value, G value, B value) before image processing, the RGB value corresponding to the target region is described as “RGB value (Rpi, Gpi, Bpi)”, and the non-target region is described. Is described as “RGB value (Rpo, Gpo, Bpo)”. Then, among the plurality of RGB values after the image processing, the RGB value corresponding to the target area is described as “RGB value (Rqi, Gqi, Bqi)”, and the RGB value corresponding to the non-target area is described as “RGB value (Rqo , Gqo, Bqo). " Further, the number of light source units corresponding to the target region is described as “SI”, and the number of light source units corresponding to the non-target region is described as “SO”. Then, the threshold of the power consumption is described as “THW”.

(Step 4-1)
The image processing unit 601 calculates the sum of the power information WIS and the power information WOS as the total power consumption WS of all the light source units included in the light emitting unit 20.

(Step 4-2)
If the total power consumption WS calculated in step 4-1 is equal to or smaller than the threshold value THW, the image processing unit 601 performs the image processing after the image processing according to Expressions 2 and 3 in the same manner as the image processing unit 107 of the first embodiment. Calculate RGB values.

  When WS> THW and (WS−THW) ≦ WOS, the image processing unit 601 calculates the RGB values after the image processing according to Equations 4 to 6 described in the first embodiment.

When WS> THW and (WS-THW)> WOS, the image processing unit 601 calculates the RGB values after image processing according to the following equations 7 to 10. The value BI is an integer value obtained by rounding up the decimal part. According to Expressions 7 to 10, the light source units are turned off for all the BL control regions corresponding to the non-target region and the BI BL control regions corresponding to the edge portion of the target region. The BL control region corresponding to a certain region is a BL control region including at least a part of the region, a BL control region including only the region, and the like.

(Rqo, Gqo, Bqo) = (0, 0, 0) (Equation 7)
BI = (WIS-THW) / (WIS / SI) (Equation 8)
Regarding BI BL control areas corresponding to the edge of the target area:
(Rqi, Gqi, Bqi) = (0, 0, 0) (Equation 9)
For other BL control areas corresponding to the target area:
(Rqi, Gqi, Bqi) = (Rpi, Gpi, Bpi) (Equation 10)

[display]
A specific example of display on the display device according to the present embodiment will be described. FIG. 7 is a schematic diagram illustrating an example of an input image. In FIG. 7, a round object 702 is drawn on a background 701, and a target area 703 including an area where the round object 702 is displayed is specified. FIG. 8 is a schematic diagram illustrating an example of a display image. From FIG. 8, it can be seen that the luminance of the central portion of the target area 703 is equal to the luminance of FIG. 7, and the luminance of the round object 702 is equal to that of FIG. Then, it can also be seen that the luminance of the region other than the central portion is reduced from the luminance of FIG. 7 so that the total power consumption WS is equal to or less than the threshold value THW.

  As described above, according to the present embodiment, if the power consumption of the display unit does not fall below the threshold even when the luminance of the non-target region is reduced, the power consumption of the target region is reduced to below the threshold. The upper limit of some display luminance ranges is further reduced. This makes it possible to more reliably reduce the power consumption of the display unit to less than the threshold value and to display a more suitable image than in the first embodiment. Specifically, in the image quality adjustment of the target area, an intended adjustment result is obtained in at least a part of the target area. Therefore, it is easy for the user to give an instruction of image quality adjustment as intended.

  In the example described above, when WS> THW and (WS-THW)> WOS, the light source unit corresponding to the non-target region and the light source unit corresponding to the edge of the target region are turned off. When the temperature becomes equal to or less than THW, those light source units may emit light. Thereby, the visibility of the display image in an area other than the central part of the target area can be improved.

<Example 3>
Hereinafter, a third embodiment of the present invention will be described. In the first embodiment, the example in which the target area (the position and the size of the target area) is specified by the user has been described. In this embodiment, an example will be described in which the ratio of the size of the target area to the size of the screen is specified by the user. In the following, different points (configuration and processing) from the first embodiment will be described in detail, and description of the same points as the first embodiment will be omitted.

[Configuration of Display Device]
FIG. 9 is a block diagram illustrating a configuration example of the display device according to the present embodiment. 9, the same functional units as in the first embodiment (FIG. 1) are denoted by the same reference numerals as in the first embodiment.

  In the present embodiment, only the ratio of the size of the target region to the size of the screen is specified by the user, and region information indicating only the ratio is input to the display device. In addition, only the ratio of the size of the non-target area to the size of the screen may be specified by the user, or both of the two ratios may be specified by the user. Region information indicating only the ratio of the size of the non-target region to the size of the screen may be input to the display device, or region information indicating both of the two ratios may be input to the display device.

  The area setting unit 901 determines the target area based on the area information (the ratio of the size of the target area to the screen size) and the input image data, and calculates the target area power calculation unit 105, the area power calculation unit 106, This is set for the processing unit 107. Note that the region setting unit 901 may set only the target region, may set only the non-target region, or may set both the target region and the non-target region.

In the present embodiment, the area setting unit 901 converts area information based on each luminance value Y output from the pixel value conversion unit 104 and table data recorded in the memory 103. Specifically, the area setting unit 901 converts the area information indicating the ratio of the size of the target area to the screen size into area information indicating the position and size of the target area (area information similar to the area information of the first embodiment).
Convert to Then, area setting section 901 outputs the converted area information to in-area power calculation section 105, out-of-area power calculation section 106, and image processing section 107. Note that the method of setting the target area is not limited to the above method (conversion and output of area information).

[Process of region setting unit 901]
A specific example of the process of the area setting unit 901 will be described.

(Step 5-1)
The region setting unit 901 calculates an average luminance value YAG of the BL control region (divided region) based on each luminance value Y output from the pixel value conversion unit 104. Then, the area setting unit 901 obtains the power consumption W corresponding to the calculated average luminance value YAG from the table data recorded in the memory 103. The process of step 5-1 is performed for each BL control area.

(Step 5-2)
The area setting unit 901 determines the number BM of the BL control areas to be selected as the target area based on area information (input area information) indicating the ratio of the size of the target area to the size of the screen. Specifically, the area setting unit 901 obtains (calculates) the number BM by multiplying the total number of the BL control areas by the above ratio (a value of 0 or more and 1 or less), as shown in Expression 11 below. ). When the value indicated by the input area information is a value (%) obtained by multiplying the above ratio of 0 or more and 1 or less by 100, the right side of Expression 11 is divided by 100.

BM = (number of all BL control areas) × (value of input area information) (Equation 11)

(Step 5-3)
The region setting unit 901 selects, as the target region, the BL control regions of the number BM determined in step 5-2 in order from the BL control region having the largest power consumption W acquired in step 5-1.

(Step 5-4)
The area setting unit 901 generates information indicating the position and size of the BL control area (several BM BL control areas) selected in step 5-3 as converted area information. Then, area setting section 901 outputs the converted area information to in-area power calculation section 105, out-of-area power calculation section 106, and image processing section 107.

  According to the processing of steps 5-1 to 5-4, of the plurality of divided areas (BL control areas) constituting the screen, the divided area having a large tone value of the input image data is preferentially set as the target area. As described above, several BM divided areas are set as target areas.

[display]
A specific example of display on the display device according to the present embodiment will be described. FIG. 10 is a schematic diagram showing an example of entering an input image. In FIG. 10, a plurality of round objects 1002 are drawn on a background 1001. The luminance value Y (gradation value) of the round object 1002 is higher than the luminance value Y of the background 1001. In FIG. 10, a plurality of areas obtained by dividing an input image by broken lines correspond to a plurality of BL control areas (a plurality of divided areas).

FIG. 11 is a schematic diagram illustrating an example of a display image. Here, it is assumed that 25% is specified as the ratio of the size of the target area to the size of the screen. In that case, each of the plurality of BL control areas respectively corresponding to the plurality of round objects 1002 is set as a target area by the above method. As a result, as shown in FIG. 11, the round object 1002 (and its surroundings) is displayed with the same luminance as the luminance of FIG. Then, the luminance of the other area is reduced from the luminance of FIG. 10 so that the total power consumption WS becomes less than the threshold value THW.

  As described above, according to the present embodiment, the ratio of the size of the target region to the size of the screen is specified by the user, and the target region is set based on the ratio. Then, control is performed so that the upper limit of the display luminance range of the non-target area is lower than the upper limit of the display luminance range of the target area so that the power consumption of the display unit is equal to or less than the predetermined power consumption. As a result, the intended adjustment result is always obtained for the area corresponding to the above ratio, so that the user can easily give the instruction of the intended image quality adjustment. For example, the user can check an intended adjustment result without specifying a target area every time the input image is changed. This embodiment is suitable for adjusting the image quality of many bright objects (stars, etc.) scattered in the night sky.

<Example 4>
Hereinafter, a fourth embodiment of the present invention will be described. In the first embodiment, an example of a display device (such as a liquid crystal display device) having a light emitting unit and a transmissive display panel has been described. In this embodiment, an example of a display device having a self-luminous display panel will be described. In the following, different points (configuration and processing) from the first embodiment will be described in detail, and description of the same points as the first embodiment will be omitted.

[Configuration of Display Device]
FIG. 12 is a block diagram illustrating a configuration example of the display device according to the present embodiment. 12, the same reference numerals as in the first embodiment denote the same functional units as in the first embodiment (FIG. 1).

  The display panel 1201 is a self-luminous display panel that displays an image on a screen by emitting light in accordance with image data output from the loading control unit 1202. For example, the display panel 1201 is an organic EL display panel, a plasma display panel, or the like.

  The loading control unit 1202 outputs image data based on the corrected image data output from the image processing unit 107 to the display panel 1201. Therefore, also in the present embodiment, the display unit is controlled based on the corrected image data as in the first embodiment. In the first embodiment, the light emitting unit 20 is controlled. In the present embodiment, the display panel 1201 is controlled. For example, when the power consumption of the display panel 1201 is equal to or less than the threshold in the display according to the corrected image data, the loading control unit 1202 outputs the corrected image data to the display panel 1201. If the power consumption of the display panel 1201 exceeds the threshold in the display according to the corrected image data, the loading control unit 1202 reduces the brightness of the corrected image data so that the power consumption of the display panel 1201 is equal to or less than the threshold. . Then, the loading control unit 1202 outputs the image data after the luminance is reduced to the display panel 1201.

  Specifically, the loading control unit 1202 applies all gradation values to the corrected image data output from the image processing unit 107 in accordance with the average gradation value (average gradation value) of the corrected image data. (Luminance of the entire image) is reduced. Then, the loading control unit 1202 outputs the processed image data to the display panel 1201.

  The memory 103 according to the present embodiment stores table data, similarly to the memory 103 according to the first embodiment. However, the table data of the present embodiment indicates the correspondence between the light emission luminance of the display element and the power consumption of the display element. Specifically, the table data of the present embodiment indicates the correspondence between the luminance value Y of the input image data and the power consumption of the display element.

[Processing of In-Region Power Calculation Unit 105]
A specific example of the process of the intra-area power calculation unit 105 according to the present embodiment will be described. The intra-region power calculation unit 105 of the present embodiment is similar to the intra-region power calculation unit 105 of the first embodiment in that the total power consumption WIS
Is calculated and output. However, the total power consumption WIS of the present embodiment is the total power consumption of all the display elements corresponding to the target area.

(Step 6-1)
The intra-region power calculation unit 105 determines (specifies) a display element corresponding to the target region based on the region information. The display element corresponding to the target area can also be referred to as a “display element arranged in the target area”. In step 6-1, a pixel (pixel of the input image data) corresponding to the target area may be determined based on the area information. The pixels corresponding to the target area may be referred to as “pixels displayed in the target area”, “pixels displayed by the display element corresponding to the target area”, and the like.

(Step 6-2)
The intra-region power calculation unit 105 extracts the luminance value Y of the pixel corresponding to the display element specified in step 6-1 from the plurality of luminance values Y output from the pixel value conversion unit 104. When a plurality of display elements are specified in step 6-1, a plurality of luminance values Y respectively corresponding to the specified plurality of display elements are extracted.

(Step 6-3)
The intra-area power calculation unit 105 acquires the power consumption WI corresponding to the luminance value Y extracted in step 6-2 from the table data recorded in the memory 103. When a plurality of brightness values Y are extracted in step 6-2, a plurality of power consumptions WI corresponding to the extracted plurality of brightness values Y are acquired.

(Step 6-4)
The intra-region power calculation unit 105 calculates the sum of all the power consumption WI acquired in step 6-3 as the total power consumption WIS, and outputs the total power consumption WIS to the image processing unit 107.

[Process of Out-of-Region Power Calculation Unit 106]
A specific example of the process of the out-of-region power calculation unit 106 according to the present embodiment will be described. The out-of-region power calculation unit 106 of the present embodiment calculates and outputs the total power consumption WOS, similarly to the out-of-region power calculation unit 106 of the first embodiment. However, the total power consumption WOS of the present embodiment is the total power consumption of all the display elements corresponding to the non-target area.

(Step 7-1)
The out-of-region power calculation unit 106 determines (specifies) a display element corresponding to the non-target region based on the region information. The display element corresponding to the non-target area can also be referred to as a “display element arranged in the non-target area”. In step 7-1, a pixel (pixel of the input image data) corresponding to the non-target area may be determined based on the area information. The pixels corresponding to the non-target region may be referred to as “pixels displayed in the non-target region”, “pixels displayed by the display element corresponding to the non-target region”, and the like.

(Step 7-2)
The out-of-region power calculation unit 106 extracts the luminance value Y of the pixel corresponding to the display element specified in step 7-1 from the plurality of luminance values Y output from the pixel value conversion unit 104. When a plurality of display elements are specified in step 7-1, a plurality of luminance values Y respectively corresponding to the specified plurality of display elements are extracted.

(Step 7-3)
The out-of-region power calculation unit 106 acquires the power consumption WO corresponding to the luminance value Y extracted in step 7-2 from the table data recorded in the memory 103. When a plurality of luminance values Y are extracted in step 7-2, a plurality of power consumption WOs corresponding to the extracted plurality of luminance values Y are acquired.

(Step 7-4)
The out-of-region power calculation unit 106 calculates the sum of all the power consumptions WO acquired in step 7-3 as the total power consumption WOS, and outputs the total power consumption WOS to the image processing unit 107.

[Processing of Image Processing Unit 107]
The image processing unit 107 of the present embodiment performs image processing based on the total power consumption WIS and WOS and the table data recorded in the memory 103 (for the non-target area), similarly to the out-of-area power calculation unit 106 of the first embodiment. Is performed on the input image data. Then, the image processing unit 107 of the present embodiment outputs the image data subjected to the image processing to the loading control unit 1202. However, in the present embodiment, the number SI is the number of display elements corresponding to the target area, and the number SO is the number of display elements corresponding to the non-target area. The total power consumption WS is the total power consumption of all the display elements included in the display panel 1201. The value K (ε) is the maximum value of the luminance value Y associated with the power consumption less than the power consumption ε in the table data recorded in the memory 103.

  As described above, according to the present embodiment, the same processing as that of the first embodiment is performed in the display device having the self-luminous display panel. Specifically, control is performed such that the upper limit of the display luminance range of the non-target area is lower than the upper limit of the display luminance range of the target area so that the power consumption of the display unit is equal to or less than the predetermined power consumption. . Thereby, the power consumption of the display unit can be reduced to less than the threshold value, and an image more suitable for the user can be displayed.

  Although the example in which the processing of the first embodiment is applied to the display device having the self-luminous display panel has been described, the processing of the second and third embodiments is applied to the display device having the self-luminous display panel. You may.

<Example 5>
The display device according to the fifth embodiment is a transmission type display device that displays an image by transmitting light emitted from a backlight unit including a plurality of light sources capable of individually emitting light through a display panel based on image data. .

  FIG. 13 is a block diagram illustrating functional blocks of the display device. The display device includes a display panel 10, a light emitting unit 20, and a control unit 500. The control unit 500 includes an input unit 501, a brightness setting unit 502, an area setting unit 503, a power consumption estimation unit 504, a brightness determination unit 505, a correction unit 506, a display control unit 507, and a brightness control unit 508.

  The control unit 500 sets the light emission luminance of each light source based on the image data, and when driving the light emission unit with the set light emission luminance, determines whether the power consumption of the light emission unit is higher than a predetermined threshold. judge. In addition, when the power consumption of the light emitting unit is higher than a predetermined threshold by driving the light emitting unit with the set light emission luminance, the control unit 500 performs a luminance correction process of reducing the set light emission luminance. Then, the light emission luminance used for controlling each light source is determined. The control unit 500 sets a target area on the screen of the display panel 10. When performing the brightness correction process, the control unit 500 does not set the light source corresponding to the target area as the target of the brightness correction process.

The input unit 501 is an interface for inputting image data. The image data is data in which the gradation values (gradation levels) of three colors of red, green, and blue (R, G, B) are specified for each of a plurality of pixels arranged in a matrix. Suppose there is. The colors for which the gradation values are specified are not limited to the above-mentioned colors. The number of colors for which gradation values are specified is not limited to three. The input unit 501 outputs image data to the luminance setting unit 502 and the correction unit 506.

  The brightness setting unit 502 sets the light emission brightness p (x, y) of each light source based on the brightness level of the image data corresponding to each light source (each light source unit) of the light emitting unit 20. Here, (x, y) indicates the coordinates of each light source in the light emitting unit 20. It is assumed that the light emission of each light source is controlled by controlling the pulse width of the current applied to the light sources. In this case, the light emission luminance p is a value obtained by normalizing the ratio (duty ratio) of the lighting period in the predetermined control period so that its maximum value is 1. The predetermined control period may be a frame period during which the display device displays an image, or may be a sub-frame period obtained by dividing the frame period.

The light emission luminance p may be a parameter corresponding to the light emission luminance of the light source. For example, the light emission luminance p may indicate the absolute value of the light emission luminance of each light source in a unit system such as nit or cd / m ² . The light emission luminance p may be a value indicating the light emission luminance of each light source as a relative value with respect to the set maximum light emission luminance. The light emission luminance p may be a value indicating the driving power of each light source.

  The brightness setting unit 502 sets the light emission brightness p according to the brightness level of the image data portion displayed in the area of the display panel 10 corresponding to each light source. The luminance level is, for example, a gradation value of each of R, G, and B of the image data, or a luminance value Y acquired from each gradation value of R, G, and B. The brightness setting unit 502 sets the emission brightness p of the corresponding light source based on the maximum value of the brightness level of the portion of the image data displayed in the area of the display panel 10 corresponding to each light source.

  FIGS. 14A and 14B are schematic diagrams showing the input image data and the light emission luminance of each light source set based on the image data. FIG. 14A is a schematic diagram illustrating image data. The broken line in the figure is a broken line for indicating the correspondence between the light source of the light emitting unit 20 and the image data, and is not a broken line drawn in the image data. The image data is data indicating an image in which objects A and B having a high luminance level are arranged on a background image having a low luminance level. It is assumed that the light emitting unit 20 has a plurality of light sources arranged in a matrix of eight in the horizontal direction and six in the vertical direction.

  FIG. 14B is a schematic diagram showing the light emission luminance p of each light source set based on the image data. The numerical value indicates the duty ratio of the PWM. The luminance setting unit 502 sets the light emission luminance of the light source including one of the objects A and B of the high luminance level in the corresponding area to 1. Further, the light emission luminance of the light source including only the background image of the low luminance level in the corresponding area is set to 0.3.

  The luminance setting unit 502 outputs information indicating the set light emission luminance p of each light source to the power consumption estimation unit 504, the luminance determination unit 505, and the correction unit 506.

  The region setting unit 503 sets a designated region on the screen of the display panel 10 that is not to be subjected to a light emission luminance correction process (described later) based on power consumption, in response to the region setting instruction. In the designated area, since the light emission luminance correction processing is not performed, it is possible to suppress a change in display luminance due to a change in image data. Therefore, the influence of the correction processing can be reduced by previously designating a region that the user wants to pay attention to or a region that is likely to be greatly affected by the fluctuation of the display luminance.

It is assumed that the area setting instruction is input by the user operating and specifying a GUI displayed on the screen. Further, the area setting unit 503 can acquire the image data, and can set an area satisfying a predetermined condition in the image data as the designated area. For example, the region setting unit 503 may set a region where the average luminance level of the image data is equal to or higher than a predetermined luminance level as the designated region. Further, the region setting unit 503 may set, as the designated region, a region in the image data having a predetermined number or more of pixels having a luminance level equal to or higher than a predetermined luminance level.

  The area setting unit 503 specifies a light source corresponding to the specified area. FIGS. 15A to 15C are schematic diagrams illustrating a designated area on the screen of the display panel 10 and a light source (designated light source) corresponding to the designated area in the light emitting unit 20. FIG. 15A is a schematic diagram showing a designated area on the screen of the display panel 10. For example, it is assumed that the user has operated the GUI while checking the image displayed on the screen based on the image data, and has instructed to specify the area Ra including the object B as the specified area.

  FIG. 15B is a schematic diagram showing the designated light source Xa corresponding to the designated area Ra. The specified area Ra is not always specified so as to match the light source area of the light emitting unit 20 (the area corresponding to the light source). It is assumed that the region setting unit 503 determines a light source in which at least a part of the light source region is at least a part of the specified region Ra as the specified light source. Note that the region setting unit 503 may set only the light source in which the entire light source region is at least a part of the specified region Ra as the specified light source. FIG. 15C is a schematic diagram showing the designated light source Xa corresponding to the designated region Ra when the light source in which all of the light source regions are at least a part of the designated region Ra is set as the designated light source. In this case, since the number of light sources (light sources that are not designated light sources) whose emission luminance is corrected based on the power consumption increases, it is possible to suppress a decrease in emission luminance of light sources other than the designated light source due to the correction processing. In other words, it is possible to reduce the amount of decrease in light emission luminance per light source.

  The area setting unit 503 outputs information indicating the specified light source to the power consumption estimation unit 504 and the luminance determination unit 505.

  The power consumption estimating unit 504 calculates the power consumption WIS of the designated light source corresponding to the designated area and the light source corresponding to the area other than the designated area when each light source is controlled by the light emission luminance set by the luminance setting unit 502. The power consumption WOS is estimated. Power consumption estimating section 504 determines whether or not the sum of power consumption WIS and power consumption WOS is greater than threshold value Th.

  As described above, it is assumed that the light emission luminance p is indicated by the duty ratio. The duty ratio is a value proportional to the current application time, and is a value corresponding to the power consumption of the light source. In the present embodiment, the power consumption estimating unit 504 calculates the sum of the power consumption WIS and the power consumption WOS based on whether or not the sum of the light emission luminances p (duty ratios) is greater than a threshold Th previously indicated by the duty ratio. It is determined whether or not it becomes larger than the threshold Th.

Here, the light emission luminance set for the designated light source is referred to as light emission luminance pi. Also, the light emission luminance set for the light source that is not the designated light source is the light emission luminance po. The power consumption WIS and the power consumption WOS are obtained by the following equations 12-1 and 12-2, respectively.

When it is determined that the sum of the power consumption WIS and the power consumption WOS is greater than the threshold Th, the power consumption estimating unit 504 determines the light emission luminance of the light source that is not the designated light source based on the power consumption WIS, the power consumption WOS, and the threshold Th. Is calculated. The coefficient α is set so that the power consumption of the light emitting unit 20 is equal to or less than the threshold Th when the designated light source is controlled by the set light emission luminance and the light source that is not the designated light source is controlled by the corrected light emission luminance. You. For example, when determining the coefficient α so that the power consumption (total value of the duty ratio) of the light emitting unit 20 is equal to the threshold Th, the coefficient α is obtained by the following equation 13.

α = (Th-WIS) / WOS (Equation 13)

  When the luminance setting unit 502 sets the light emission luminance of each light source as shown in FIG. 14B and sets the threshold Th to 15, it is determined that the sum of the power consumption WIS and the power consumption WOS is larger than the threshold Th. You. Then, the coefficient α is calculated as 0.51 (≒ (15.0−7.6) /14.5).

  Power consumption estimation section 504 outputs to luminance determination section 505 a determination result indicating whether the sum of power consumption WIS and power consumption WOS is greater than threshold value Th. When determining that the sum of power consumption WIS and power consumption WOS is greater than threshold value Th, power consumption estimation section 504 outputs calculated coefficient α to luminance determination section 505.

  The luminance determination unit 505 corrects the emission luminance of each set light source based on the determination result obtained from the power consumption estimation unit 504 and the coefficient α, and determines the emission luminance for controlling the light emission unit 20. . When the power consumption estimating unit 504 determines that the sum of the power consumption WIS and the power consumption WOS is equal to or smaller than the threshold Th, the brightness determination unit 505 determines the emission brightness of each light source acquired from the brightness setting unit 502 as the brightness control unit 508. Output to

  When the power consumption estimating unit 504 determines that the sum of the power consumption WIS and the power consumption WOS is larger than the threshold Th, the luminance determination unit 505 specifies the emission luminance of each light source acquired from the luminance setting unit 502. The light emission luminance of the light source that is not the light source is corrected using the coefficient α.

  FIG. 16 is a schematic diagram showing the light emission luminance of each light source after correction by the luminance determination unit 505. The light emission luminance of the light sources other than the designated light source Xa is reduced as compared with the light emission luminance shown in FIG. More specifically, in the light sources other than the designated light source Xa, the light emission luminance (duty ratio) of which is set to 1 is corrected to 0.51, and the light emission luminance (duty ratio) is set to 0.3. The emission luminance of the light source is corrected to 0.15. On the other hand, the emission luminance of the designated light source Xa does not change from the value set by the luminance setting unit 502. At this time, when the total amount of power consumption is calculated based on the emission luminance determined by the luminance determining unit 505, the total amount of power consumption is equal to or less than the threshold Th.

  The brightness control unit 508 controls the brightness of each light source using the emission brightness of each light source determined by the brightness determination unit 505. When the light emission luminance is indicated by the duty ratio, the luminance control unit 508 controls each light source by PWM driving at the duty ratio indicating the light emission luminance.

  The correction unit 506 corrects the image data based on the acquired light emission luminance of each light source (the light emission luminance set by the luminance setting unit 502). The correction unit 506 estimates the intensity distribution of light applied to the display panel 10 when the light emitting unit 20 emits light at the emission luminance set for each light source. The correction unit 506 acquires, from the memory, a distribution function indicating a distribution of light emitted to the display panel 10 when a certain light source emits light. The correction unit 506 estimates the light intensity distribution formed by combining the light emitted from each light source on the back surface of the display panel 20 using the emission luminance of each light source and the distribution function. Note that the correction unit 506 may use the light emission luminance determined by the luminance determination unit 505 instead of the light emission luminance set by the luminance setting unit 502.

The correction unit 506 performs a process of dividing the pixel value of the image data by the intensity of light applied to the position of the display panel 10 corresponding to the pixel to obtain a corrected pixel value for each of the image data. This is performed for pixels. The luminance (intensity) of light emitted to the back surface of the display panel 10 when each light source of the light emitting unit 20 is driven at a predetermined duty ratio is defined as a reference intensity Lt. The intensity of light applied to the position (x, y) of the display panel 10 corresponding to the pixel (x, y) is defined as L (x, y). The correction unit 506 multiplies the pixel value of the image data corresponding to the position (x, y) of the display panel 10 by Lt / L (x, y) to obtain a corrected pixel value. It is assumed that the intensity of light emitted when driven by the light emission luminance of each light source set based on the image data by the luminance setting unit 502 decreases from the reference intensity Lt. The correction unit 506 corrects the image data to suppress the effect of the reduction. The correction unit 506 outputs the corrected image data to the display control unit 507.

  The display control unit 507 controls the transmittance of the display panel 10 based on the image data acquired from the correction unit 506. The correction unit 506 corrects the image data based on the light emission luminance of each light source of the light emitting unit 20, thereby controlling a plurality of light sources corresponding to a plurality of regions having the same pixel value of the image data before correction with different light emission luminances. Even so, the brightness displayed in those areas is substantially the same.

  FIG. 17 is a schematic diagram illustrating a control flow of the light emission luminance in the present embodiment.

  First, in step S1701, the brightness setting unit 502 sets the light emission brightness p (x, y) of each light source based on the brightness level of the image data corresponding to each light source of the light emitting unit 20. Here, it is assumed that the designated area has been set by the area setting unit 503. Therefore, the light emission luminance pi (x, y) and light emission luminance po (x, y) are set by the processing of step 1701.

  Next, in step S1702, the power consumption estimating unit 504 calculates the power consumption WIS and WOS based on the emission luminances pi (x, y) and po (x, y) set in step S1701. The power consumptions WIS and WOS are calculated using the above equations 12-1 and 12-2.

  Then, in step S1703, power consumption estimating section 504 determines whether or not the sum of power consumption WIS and power consumption WOS is greater than threshold value Th based on power consumption WIS and WOS calculated in step S1702. If it is determined that the sum of the power consumption WIS and the power consumption WOS is larger than the threshold Th, the process proceeds to step S1704. If it is determined that the sum is equal to or smaller than the threshold Th, the process proceeds to step S1706. Proceed.

  In step S1704, power consumption estimation section 504 calculates coefficient α based on power consumption WIS, WOS calculated in step S1702 and threshold value Th. The coefficient α is calculated using Expression 13 described above.

  Next, in step S1705, the luminance determination unit 505 multiplies the light emission luminance po (x, y) set in step S1701 for the light source that is not the designated light source by the coefficient α calculated in step S1704. , The light emission luminance po ′ (x, y). Thereafter, the process proceeds to step S1706.

In step S1706, the brightness control unit 508 controls the brightness of each light source using the emission brightness of each light source determined by the brightness determination unit 505. If it is determined in step S1703 that the sum of the power consumption WIS and the power consumption WOS is equal to or smaller than the threshold Th, the light emission luminance p (x, y) equal to the light emission luminance p (x, y) of each light source set in step S1701 is set. The brightness of each light source is controlled by using this. If it is determined in step S1703 that the sum of the power consumption WIS and the power consumption WOS becomes larger than the threshold Th, the specified light source is the same as the light emission luminance pi (x, y) set in step S1701. The luminance is controlled using the light emission luminance. For the light source that is not the designated light source, the luminance is controlled using the light emission luminance po ′ (x, y) obtained in step S1705.

  FIGS. 18A, 18B, and 19 are schematic diagrams showing the effects obtained when the control of this embodiment is performed. It is assumed that the image data to be displayed is the same as the image data shown in FIG. The light emission luminance of each light source set by the luminance setting unit 502 based on the image data in FIG. 14A is assumed to be the light emission luminance shown in FIG. Assuming that the threshold value Th is 15, the total power consumption W when the light emitting unit 20 is driven at the set light emission luminance of each light source is 22.1, which is larger than the threshold value Th.

  In the case where the control of the present embodiment is not performed, in order to make the power consumption of the light emitting unit 20 equal to or less than the threshold Th, the light emission luminance of each light source set by the luminance setting unit 502 is multiplied by Th / W. The light emission of the light source is controlled. FIGS. 18A and 18B are schematic diagrams illustrating a comparative example when the control of the present embodiment is not performed. FIG. 18A is a schematic diagram illustrating light emission luminance used for controlling each light source when all the light sources are subjected to the adjustment processing without performing the control of the present embodiment. From the set light emission luminance shown in FIG. 14B, the light emission luminance decreases for all the light sources. FIG. 18B is a schematic diagram illustrating an image displayed on the display panel 10 when each light source is controlled with the light emission luminance illustrated in FIG. Since the light emission luminance is controlled to be uniformly lower than the light emission luminance set based on the image data, the displayed image is entirely darker than when the light emission luminance adjustment processing is not performed.

  FIG. 19 is a schematic diagram illustrating an image displayed on the display panel 20 when the control of this embodiment is performed. As a result of performing the control of the present embodiment, the light emission luminance adjustment processing is not executed for the designated light source Xa. Therefore, in the region (target region Ra) corresponding to the designated light source Xa, an image is displayed with the same luminance as the luminance displayed when the light emitting unit 20 is controlled with the set light emission luminance pi. On the other hand, a light source that is not the designated light source Xa is controlled at a light emission luminance po ′ lower than the set light emission luminance po. Therefore, in an area corresponding to a light source other than the designated light source Xa, an image is displayed at a lower luminance than the luminance displayed when the light emitting unit 20 is controlled at the set light emission luminance po.

  The process of adjusting the light emission brightness for the light source is a process of controlling the upper limit of the display brightness of the area corresponding to the light source. By executing the adjustment process (reduction process) of the light emission luminance of the light source based on the power consumption, the upper limit value of the luminance that can be displayed in the region corresponding to the light source is reduced. For example, it is assumed that the light emission luminance corresponding to the maximum possible duty ratio of the light source is set for the light source corresponding to a certain area including the white area. When the light emission luminance of the light source is reduced by the adjustment processing based on the power consumption, the display luminance of the white area is reduced. The display luminance of the white area corresponds to the upper limit of the luminance that can be displayed in the area including the white area.

  According to the present embodiment, the light source (designated light source) corresponding to the designated area (target area) is not subjected to the adjustment processing based on the power consumption, so that it is possible to suppress the fluctuation of the display brightness of the target area. It becomes.

  Thus, for example, when a user is editing image data, by designating a region including a point of interest in advance as a target region, the effect of power consumption on display brightness can be reduced, and stability can be improved. Work.

<Example 6>
In the display devices according to the first to fifth embodiments, a part of the input image data is designated as the region of interest, and the brightness of the backlight unit corresponding to the designated region is not subjected to the adjustment processing based on the power consumption. Controlled. In the case of a self-luminous display device, control is performed so that pixels belonging to an area are not subjected to adjustment processing based on power consumption.

  In the sixth embodiment, when a plurality of image data are displayed on one screen, the area corresponding to the image data specified by the user is not subjected to the adjustment processing based on the power consumption, thereby suppressing the fluctuation of the display luminance of the target area. I do.

  FIG. 20 is a block diagram illustrating functional blocks of the display device. The display device includes a display panel 10, a light emitting unit 20, and a control unit 600. The control unit 600 includes a first input unit 601, a second input unit 602, a screen synthesis unit 603, an area setting unit 604, a brightness setting unit 502, a power consumption estimation unit 504, a brightness determination unit 505, a correction unit 506, and a display control unit. 507 and a brightness control unit 508. The description of the functions described in the other embodiments is omitted.

  The control unit 600 receives the two types of image data, sets the light emission luminance of each light source based on the combined image data obtained by combining them, and drives the light emission unit with the set light emission luminance. It is determined whether the power consumption is higher than a predetermined threshold. Further, when the power consumption of the light emitting unit becomes higher than a predetermined threshold by driving the light emitting unit with the set light emitting luminance, the control unit 600 executes a luminance correction process for reducing the set light emitting luminance. Then, the light emission luminance used for controlling each light source is determined. The control unit 600 selects at least one piece of image data from among the received plurality of pieces of image data as target image data according to a user operation. Then, control unit 600 sets an area corresponding to the specified image data on the screen of display panel 10 as a specified area (target area). When performing the brightness correction process, the control unit 600 does not set the light source corresponding to the designated area as the target of the brightness correction process.

  Each of the first input unit 601 and the second input unit 602 is an interface for inputting (receiving) image data, similarly to the input unit 501 of the fifth embodiment. Each of the first input unit 601 and the second input unit 602 outputs the input image data to the screen combining unit 603.

  The screen synthesizing unit 603 synthesizes an image (input image data) input (received) by the first input unit 601 and an image (input image data) input by the second input unit 602, thereby forming a synthesized image. (Synthesized image data). For example, a composite image is generated by arranging two input images (input image data) so as to fit on one screen of the display panel 10. Here, it is assumed that the images shown in FIGS. 21A and 21B have been input. FIGS. 21A and 21B show images captured by the same video camera, for example. FIG. 21A shows an image output according to the SDR standard, and FIG. 21B shows an image output according to the HDR standard. The SDR stands for Standard Dynamic Range. For example, the conventional broadcast standard ITU-R BT. 709 (ITU: International Telecommunication Union) is a dynamic range of image data. HDR stands for High Dynamic Range, which has a wider dynamic range than SDR. If the image size of each input image is the same as the image size of the display panel 10 (screen size; display size), a process of reducing the image size is performed on each input image, and two input images are displayed as shown in FIG. A composite image in which the image is contained on one screen is generated. The screen combining unit 603 outputs the combined image to the correcting unit 506 and the brightness setting unit 502.

The area setting unit 604 specifies the light source corresponding to the specified area, similarly to the area setting unit 503. In the present embodiment, the area setting unit 604 selects at least one of the plurality of pieces of input image data as designated image data according to a user operation. Then, the area setting unit 604 calculates an image area in which the designated image data is arranged in the combined image data generated by the screen combining unit 603 as a designated area, and designates a light source (designated light source) corresponding to the designated area (specification). ). Since the light emission luminance correction processing is not performed in the designated area, it is possible to reduce the influence of the correction processing on input image data (designated image data) viewed by the user as a reference. The user operation is, for example, an operation of specifying input image data,
This is an operation on a physical switch or a GUI displayed on the screen. When no user operation is performed, one of the two pieces of input image data that is determined in advance may be selected as the designated image data. When the two input image data are an image output according to the HDR standard (HDR image data) and an image output according to the SDR standard (SDR image data), the SDR image data is designated as designated image data. , Can be set in advance by the user. The area setting unit 604 outputs information indicating the specified light source to the power consumption estimation unit 504 and the luminance determination unit 505.

  According to the present embodiment, the light source (designated light source) corresponding to the designated image data area (target area; designated area) is not subjected to the adjustment processing based on the power consumption, so that the display luminance of the designated image data is obtained. Can be suppressed. In an image production site or the like, when simultaneously checking the SDR image and the HDR image, the HDR image may be adjusted based on the SDR image. According to the present embodiment, it is possible to reduce the influence of the power consumption on the display luminance with respect to the reference SDR image, so that it is possible to work stably.

  In the present embodiment, an example in the case of two inputs has been described. However, the function (processing) of the present embodiment can be applied to the case of four inputs. That is, the number of input units may be more than two, and the number of input image data may be more than two. In that case, two or more input image data may be selected as designated image data (input image data whose luminance is to be fixed).

  In this embodiment, the power consumption is estimated based on the composite image. However, if an impression (display luminance or the like) of an input image that is not a designated image (designated image data) greatly deviates from an impression when only the input image is displayed on one screen due to a loading process (an adjustment process based on power consumption). In some cases, stable editing work becomes difficult. For example, the impression of the image when only the image of FIG. 21B is displayed on one screen and the impression of the image of FIG. 21B when the composite image of FIG. If different, stable editing work may be difficult. Therefore, the power consumption when only the input image that is not the designated image is displayed (on the full screen) is further estimated, and the power consumption when displaying only the input image that is not the designated image and the composite image are displayed (on the full screen). The power consumption in the case may be compared. Then, the luminance may be adjusted based on the larger of the power consumptions. The corrected image (corrected image data) described in the first embodiment and the like may be generated based on the larger power consumption and a predetermined power consumption (threshold). Thus, it is possible to suppress a difference (shift) between the impression of each input image when displaying the composite image and the impression when only the input image is displayed.

  In the power consumption estimating units 504 of the fifth and sixth embodiments, the power consumption WIS of the designated light source corresponding to the designated area is estimated for each frame. However, the power consumption WIS varies due to a slight change in the image data of the designated area. In this case, since the coefficient α used for correcting the light emission luminance of the light source that is not the designated light source also varies, the luminance outside the designated area varies, and the user may feel a sense of obstruction. Therefore, the power consumption estimating unit 504 may estimate and calculate the maximum power consumption of the designated light source (the maximum power consumption assumed in the designated area), and use that value as the power consumption WIS. The calculation for estimating the maximum power consumption may be performed when the user instructs a change in the setting of the display device, such as a change in the setting of the designated area or a change in the setting of the display luminance. This may be performed when the format of the input image data is changed. Based on the maximum power consumption assumed in the designated area (target area), the power consumption based on the composite image data in the non-target area, and the predetermined power consumption (threshold), the corrected image data described in the first embodiment and the like is calculated. May be generated. Thereby, even if the image data in the designated area slightly fluctuates, the fluctuation of the luminance outside the designated area can be suppressed, so that the user can work stably.

Each functional unit of the first to sixth embodiments may or may not be individual hardware. The functions of two or more functional units may be realized by common hardware. Each of a plurality of functions of one functional unit may be realized by individual hardware. Two or more functions of one functional unit may be realized by common hardware. Also, each functional unit may or may not be realized by hardware. For example, the device may have a processor and a memory in which a control program is stored. Then, the functions of at least some of the functional units of the device may be realized by the processor reading out the control program from the memory and executing the control program.

  In the first to sixth embodiments, it is estimated that the power at the time of the loading process exceeds the threshold. However, the loading process may be determined by a panel module or a backlight module. In this case, information on the determined loading process may be received from the panel module or the backlight module. Then, based on the received information, the image data of the non-target area may be corrected without correcting the image data of the target area, and the corrected image data may be input to the panel module or the backlight module. With this, the same effect can be obtained.

  Embodiments 1 to 6 are merely examples, and configurations obtained by appropriately modifying or changing the configurations of Embodiments 1 to 6 within the scope of the present invention are also included in the present invention. A configuration obtained by appropriately combining the configurations of Examples 1 to 6 is also included in the present invention.

<Other examples>
The present invention supplies a program for realizing one or more functions of the above-described embodiments to a system or an apparatus via a network or a storage medium, and one or more processors in a computer of the system or the apparatus read and execute the program. It can also be realized by the following processing. It can also be realized by a circuit (for example, ASIC) that realizes one or more functions.

10: Display panel 20: Light emitting unit 100: Control unit 107: Image processing unit 601: Image processing unit 1201: Display panel

A first aspect of the present invention provides :
Display means for displaying the images on the screen,
Setting means for setting a first area of the screen according to a user operation;
Control means for controlling the display means to display an image on the screen of the display means based on the input image data,
With
The first area is an area that does not change even when the input image data changes,
Said control means such that said power consumption of the display unit becomes equal to or lower than a predetermined power consumption, than the previous SL upper limit of the display luminance range of the first area of the display unit, the first of said screen of said display means It intends row control to lower the upper limit value of the display luminance range of the second region not 1 region
It is a display device comprising a call.

A second aspect of the present invention provides :
A control method of a display device comprising display means for displaying images on the screen,
A setting step of setting a first area of the screen according to a user operation;
A control step of controlling the display means to display an image on the screen of the display means based on the input image data;
Have
The first area is an area that does not change even when the input image data changes,
In the control step, the so power consumption of the display unit becomes equal to or lower than a predetermined power consumption, than the previous SL upper limit of the display luminance range of the first area of the display unit, the first of said screen of said display means It intends row control to lower the upper limit value of the display luminance range of the second region not 1 region
It shall be the feature and this system is a control method.

Claims (19)

Display means for displaying an image based on the input image data on a screen;
It is not the first area of the screen of the display means than the upper limit of the display luminance range of the first area of the screen of the display means so that the power consumption of the display means is equal to or less than a predetermined power consumption. Control means for performing control to lower the upper limit value of the display luminance range of the second area;
A display device comprising: The display device according to claim 1, wherein the upper limit value of the display luminance range is a display luminance when a white area of the input image data is displayed on the display unit. The display device according to claim 1, further comprising a setting unit configured to set the first area in accordance with a user operation. 4. The apparatus according to claim 3, wherein the setting unit sets the first area based on a ratio of a size of the first area to a size of the screen specified by a user and the input image data. A display device according to claim 1. Input means for receiving a plurality of input image data,
Combining means for combining the plurality of input image data to generate combined image data;
Further comprising
The setting means selects at least one input image data from the plurality of input image data according to a user operation, and selects the selected input image data with respect to the synthesized image data generated by the synthesizing means. 4. The display device according to claim 3, wherein a region in which is disposed is set as the first region. 5. The control means, so that the upper limit value of the display brightness range of a part of the first area set in the setting means is lower than the upper limit value of the display brightness range of another part of the first area, The display device according to any one of claims 3 to 5, wherein the display device is controlled. The control means, the upper limit value of the display brightness range of the edge portion of the first area set by the setting means is lower than the upper limit value of the display brightness range of the center portion of the first area, The display device according to claim 6, wherein the display device is controlled. The control unit controls the display unit based on corrected image data in which a gradation value of a portion of the input image data corresponding to the second region of the screen is reduced, so that a display luminance of the second region is displayed. The display device according to any one of claims 1 to 7, wherein the upper limit value is reduced. The control unit controls the display unit based on the corrected image data in which a gradation value of a portion of the input image data corresponding to the second area is reduced by a coefficient based on the predetermined power consumption. The display device according to claim 8, wherein: The control unit is configured to control a power consumption when an image is displayed on the display unit based on the input image data, and a floor of a portion of the input image data corresponding to the second area based on the predetermined power consumption. The display device according to claim 9, wherein the correction image data is generated by reducing a tone value. The control means includes
The maximum power consumption assumed in the first area, the power consumption based on the composite image data in the second area, and the part of the composite image data corresponding to the second area based on the predetermined power consumption. Generate corrected image data by reducing the gradation value,
The display device according to claim 5, wherein an upper limit value of display luminance of the second area is reduced by controlling the display unit based on the corrected image data. The control means includes
Among the plurality of input image data, the power consumption when only the unselected input image data is displayed is compared with the power consumption when the composite image data is displayed, and the larger one of the power consumptions is compared. And generating the corrected image data by reducing the gradation value of the portion of the composite image data corresponding to the second region based on the predetermined power consumption and the predetermined power consumption.
The display device according to claim 5, wherein an upper limit value of display luminance of the second area is reduced by controlling the display unit based on the corrected image data. The display device according to claim 1, wherein the display unit is a self-luminous display panel. The display means,
A plurality of light sources,
A transmission type display panel that displays the image on the screen by transmitting light emitted from the plurality of light source units based on the input image data,
With
The control means includes
Brightness setting means for setting the light emission brightness of each light source unit based on the brightness level of the portion of the input image data corresponding to each light source unit,
A light emission control unit that controls each light source unit based on the light emission luminance of each light source unit set by the luminance setting unit,
With
The light emission control unit, when the power consumption when controlling each light source unit with the set light emission luminance of each light source unit becomes larger than the predetermined power consumption,
Of the plurality of light source units, a light source unit corresponding to the first region is controlled to emit light at the emission luminance set for the light source unit,
The light source unit corresponding to the second region among the plurality of light source units is controlled to emit light with a light emission luminance lower than the light emission luminance set for the light source unit. The display device according to claim 1. The light emission control means is set in the light source unit corresponding to the second area based on the power consumption and the predetermined power consumption when each light source unit is controlled by the set light emission luminance of each light source unit. The display device according to claim 14, wherein the light emission luminance is corrected. The control unit corresponds to the second area of the input image data based on the power consumption and the predetermined power consumption when each light source unit is controlled by the set light emission luminance of each light source unit. Further comprising processing means for correcting the gradation value of the portion to generate corrected image data,
The display device according to claim 14, wherein the light emission control unit controls light emission luminance of each light source unit based on the corrected image data. A display step of displaying an image based on the input image data on a screen of the display means,
It is not the first area of the screen of the display means than the upper limit of the display luminance range of the first area of the screen of the display means so that the power consumption of the display means is equal to or less than a predetermined power consumption. A control step of performing control to lower the upper limit value of the display luminance range of the second area;
A control method for a display device, comprising:   A program for causing a computer to function as each unit of the display device according to claim 1.   A computer-readable storage medium storing a program for causing a computer to function as each unit of the display device according to claim 1.

Images