JP2015031879A - Display device, control method of display device, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technology with which the light emission luminance of light sources can be controlled to appropriate values without delaying the display of an image.SOLUTION: A display device of the present invention includes light emitting means having a plurality of light sources, a display panel, and control means for controlling the light emission luminance of the light sources. The control means acquires the feature amounts of images to be displayed in a plurality of respective areas on a screen corresponding to the plurality of light sources from image data N-frames before a frame being displayed, and determines target luminances of the light sources corresponding to the areas on the basis of the acquired feature amounts of the areas. The control means includes: estimation means for estimating a movement destination area in which a moving body present in an image N-frames before the frame being displayed can move in the image in the frame being displayed, on the basis of changes in the feature amounts during periods of a plurality of frames N- or more-th frame before the frame being displayed; and correction means for correcting the target luminance of the light sources corresponding to the movement destination area.

Description

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

  In recent years, in a display device using liquid crystal (liquid crystal display device), based on input image data, among a plurality of light sources included in a backlight, the light emission luminance of some light sources is set to a value different from the light emission luminance of other light sources. There is a technology to control. Such control is called local deming control, and by performing local deming control, the contrast of the display image can be improved and black float can be reduced. There is also a technique for performing local dimming control and correcting input image data in accordance with the light emission luminance of each light source (Patent Document 1).

In the local deming control, for example, the light emission luminance of each light source is controlled based on a feature amount (a feature amount representing the brightness of an image) acquired from image data. However, in general, a delay of one frame period or more occurs in the control of the light emission luminance. Specifically, it is common that a delay of one frame period or more occurs in the acquisition of the feature amount.
Then, if the emission luminance is controlled based on the feature amount acquired from the image data of the frame (acquisition frame) before the image frame (display frame) to be displayed on the display device, the display image (displayed on the screen) is displayed. Image quality) may be deteriorated. For example, if the luminance and luminance distribution of image data differ greatly between the display frame and the acquisition frame, the light emission luminance is controlled to a value inappropriate for the display frame, and the image quality is greatly degraded.
In the technique disclosed in Patent Document 1, the display frame is made to coincide with the acquisition frame by delaying the display frame. However, if the display frame is delayed, the immediacy of image display is lost, or a frame memory for delay is required.

JP 2002-099250 A

  An object of this invention is to provide the technique which can control the light emission luminance of each light source to an appropriate value, without delaying the display of an image.

The first aspect of the present invention is:
A light emitting means having a plurality of light sources capable of individually controlling the light emission brightness;
A display panel that displays an image on a screen by modulating light from the light emitting means;
Control means for controlling the light emission luminance of each light source according to the brightness of the image to be displayed in the area on the screen corresponding to each of the plurality of light sources;
In a display device having
For each of a plurality of regions corresponding to the plurality of light sources, the control means sets a feature amount representing the brightness of an image to be displayed in the region N frames before the display frame (N is an integer of 1 or more). The target luminance of the light source corresponding to each area is determined based on the acquired feature amount of each area.
The control means includes
A moving destination that is a region where a moving body existing in the image before N frames can move in the image of the display frame based on a change in feature amount in a period of a plurality of frames N frames or more before the display frame An estimation means for estimating a region;
Correction means for correcting the target luminance of the light source corresponding to the destination area estimated by the estimation means;
It is a display device characterized by having.

The second aspect of the present invention is:
A light emitting means having a plurality of light sources capable of individually controlling the light emission brightness;
A display panel that displays an image on a screen by modulating light from the light emitting means;
A display device control method comprising:
A control step of controlling the light emission luminance of each light source according to the brightness of an image to be displayed in an area on the screen corresponding to each of the plurality of light sources;
In the control step, for each of a plurality of areas corresponding to the plurality of light sources, a feature amount representing the brightness of an image to be displayed in the area is displayed N frames before the display frame (N is an integer of 1 or more). The target luminance of the light source corresponding to each area is determined based on the acquired feature amount of each area.
In the control step,
A moving destination that is a region where a moving body existing in the image before N frames can move in the image of the display frame based on a change in feature amount in a period of a plurality of frames N frames or more before the display frame An estimation step for estimating a region;
A correction step of correcting the target luminance of the light source corresponding to the destination area estimated by the estimation step;
A control method for a display device, comprising:

  According to a third aspect of the present invention, there is provided a program that causes a computer to execute each step of the display device control method described above.

  According to the present invention, the light emission luminance of each light source can be controlled to an appropriate value without delaying image display.

1 is a block diagram showing an example of a functional configuration of a liquid crystal display device according to Embodiment 1. FIG. The figure which shows the specific example of the process which concerns on Example 1. FIG. The figure which shows the specific example of the process which concerns on Example 1. FIG. The figure which shows the specific example of the process which concerns on Example 2. FIG. Schematic diagram showing an example of region estimation processing and target luminance correction processing according to the second embodiment

<Example 1>
Hereinafter, a display device and a control method thereof according to Embodiment 1 of the present invention will be described.
In this embodiment, an example in which the display device is a transmissive liquid crystal display device will be described. However, the display device is not limited to a transmissive liquid crystal display device. The display device may be a display device having an independent light source. For example, the display device may be a reflective liquid crystal display device. Further, the display device may be a MEMS shutter system display using a MEMS (Micro Electro Mechanical System) shutter instead of the liquid crystal element.

(overall structure)
FIG. 1 is a block diagram illustrating an example of a functional configuration of the liquid crystal display device according to the present embodiment.

  The backlight 5 is a light emitting unit having a plurality of light sources capable of individually controlling light emission luminance. The light source has one or more light emitting members. As the light emitting member, for example, an LED, an organic EL element, a cold cathode tube, or the like can be used. Light from the backlight 5 is applied to the back surface of the liquid crystal panel 7.

  The liquid crystal panel 7 is a display panel that displays an image on a screen by modulating light from the backlight 5. Specifically, the liquid crystal panel 7 has a plurality of liquid crystal elements, and controls the transmittance of each liquid crystal element based on image data. Then, the light from the backlight 5 passes through each liquid crystal element, whereby an image is displayed on the screen.

The control unit 9 controls the light emission luminance of each light source according to the brightness of the image to be displayed in the area on the screen corresponding to each of the plurality of light sources included in the backlight 5. Specifically, the control unit 9 outputs, for each light source, a backlight control value corresponding to the brightness of the image to be displayed in the area corresponding to the light source. Each light source emits light with a light emission luminance corresponding to the backlight control value.
In this embodiment, it is assumed that a plurality of divided areas constituting a screen area are set as a plurality of areas corresponding to a plurality of light sources. Specifically, it is assumed that n horizontal areas (n is an integer of 2 or more) and m vertical areas (m is an integer of 2 or more) in the horizontal direction are set. However, the area corresponding to the light source is not limited to this. For example, as an area corresponding to a light source, an area overlapping with an area corresponding to another light source may be set, or an area not in contact with an area corresponding to another light source may be set.
In this embodiment, a plurality of different divided areas are set as a plurality of areas corresponding to a plurality of light sources, but the present invention is not limited to this. For example, the same area as that corresponding to another light source may be set as the area corresponding to the light source.

  The correction coefficient determination unit 6 and the correction processing unit 8 perform a compensation process for compensating for a change in luminance on the screen due to a change in the light emission luminance of the light source. In this embodiment, compensation processing is performed on input image data (image data input to the liquid crystal display device). Then, the image data subjected to the compensation process is input to the liquid crystal panel 7, and the transmittance of the liquid crystal panel 7 is controlled to the transmittance corresponding to the image data subjected to the compensation process.

The correction coefficient determination unit 6 determines a correction coefficient for correcting the pixel value of the image data based on the light emission luminance of each light source. In this embodiment, the correction coefficient determination unit 6 calculates the luminance distribution of the backlight light (light from the backlight 5) in the screen based on the backlight control value of each light source output from the control unit 9. . Then, the correction coefficient determination unit 6 determines a correction coefficient for each pixel based on the calculated luminance distribution.
Note that the correction coefficient may be calculated using a function representing a correspondence relationship between the luminance of the backlight light and the correction coefficient, or may be determined using a table representing the correspondence relationship.
The correction coefficient may be determined for each divided region (region corresponding to the light source). For example, for each divided area, a common correction coefficient may be determined for each pixel in the divided area according to the backlight control value of the light source corresponding to the divided area. In the case of such a configuration, a function or a table indicating the correspondence between the backlight control value and the correction coefficient may be used.

  The correction processing unit 8 corrects the input image data using the correction coefficient determined by the correction coefficient determination unit 6. Specifically, for each pixel, the pixel value of the pixel is multiplied by a correction coefficient corresponding to the pixel. Then, the correction processing unit 8 outputs the corrected image data to the liquid crystal panel 7.

(Control part)
In the present embodiment, the control unit 9 sets, for each of a plurality of regions corresponding to a plurality of light sources, a feature amount representing the brightness of an image to be displayed in the region N frames before the display frame (N is 1). The target luminance of the light source corresponding to each area is determined based on the acquired feature amount of each area.
Specifically, the control unit 9 includes a feature amount acquisition unit 1, a backlight control value determination unit 2, a region estimation unit 3, a backlight control value correction unit 4, and the like.

The feature amount acquisition unit 1 acquires a feature amount for each divided region from the input image data. It takes time to acquire the feature amount. Therefore, the feature amount acquisition unit 1 acquires the feature amount of the input image data N frames before the display frame. The display frame is a frame of image data that is corrected by the correction processing unit 8 and input to the liquid crystal panel 7. That is, the acquisition of the feature amount is delayed by N frames with respect to the control of the transmittance of the liquid crystal panel 7. In this embodiment, a case where N = 1 is described. In this embodiment, an example in which the feature amount is the maximum pixel value in the divided area will be described.
Note that the feature amount is not limited to the maximum pixel value. For example, representative values of pixel values (maximum value, minimum value, mode value, intermediate value, average value, etc.), histograms, representative values or histograms of luminance values, and the like may be acquired as feature amounts.
The feature amount acquisition unit 1 sends the acquired (detected) feature amount to the backlight control value determination unit 2 and the region estimation unit 3.

The region estimation unit 3 is a region in which a moving body existing in the image before N frames can move in the image of the display frame based on a change in the feature amount in a period of a plurality of frames N frames or more before the display frame. The destination area is estimated. Further, the region estimation unit 3 is a region in which a moving body is present in the image before the N frames, but no moving body is present in the image of the display frame, based on the change in the feature amount during the plurality of frames. Further estimate the disappearance region.
Specifically, the region estimation unit 3 records the feature quantities for the plurality of frames in a storage unit (not shown). Then, the region estimation unit 3 estimates the movement destination region and the disappearance region using the feature amounts for the plurality of frames stored in the storage unit.
In the present embodiment, the region estimation unit 3 determines the movement of the moving body during the plurality of frames based on the change in the feature amount during the plurality of frames, and the destination region based on the determined movement of the moving body. Estimate the disappearance area.
The area estimation unit 3 sends a control value correction map representing the estimation result of the destination area and the disappearance area to the backlight control value correction unit 4.

The backlight control value determination unit 2 determines the backlight control value of the light source corresponding to the divided area for each divided area based on the feature amount of the divided area. As described above, in this embodiment, the light emission luminance is controlled to a value corresponding to the backlight control value. Therefore, it can also be said that the backlight control value is a value representing the target value (target luminance) of the light emission luminance. In this embodiment, the backlight control value for each divided region (for each light source) is determined so that the light emission luminance is high in the bright region of the image and the light emission luminance is low in the dark region of the image. Specifically, the higher the target luminance, the higher the backlight control value is determined as the feature amount (the maximum pixel value) is higher. The backlight control value is determined using, for example, a function or table that represents the correspondence between the feature amount and the backlight control value.
The backlight control value determination unit 2 sends the determined backlight control value to the backlight control value correction unit 4.

The backlight control value correction unit 4 corrects the target luminance (backlight control value determined by the backlight control value determination unit 2) of the light source corresponding to the movement destination region estimated by the region estimation unit 3. Further, the backlight control value correction unit 4 further corrects the target luminance of the light source corresponding to the disappearance region estimated by the region estimation unit 3.
The backlight control value correction unit 4 controls the light emission luminance to the corrected target luminance for the light source corresponding to the movement destination region and the light source corresponding to the disappearance region, and the light emission luminance for the remaining light sources. Is controlled to the target luminance determined by the backlight control value determination unit 2. Specifically, the backlight control value correction unit 4 causes the light source corresponding to the movement destination area and the light source corresponding to the disappearance area to emit light with the corrected backlight control value, and the remaining light sources are set to the backlight control value. Light is emitted with the backlight control value determined by the determination unit 2.

(Area estimation part)
The operation of the area estimation unit 3 will be described in detail.
In a storage unit (not shown), feature quantities for two frames are recorded as feature quantities for a plurality of frames N frames or more before the display frame. As described above, in this embodiment, N = 1. In the storage unit, the feature amount of the frame immediately before the display frame and the feature amount of the frame immediately before the display frame are recorded.

  For each divided region, the region estimation unit 3 determines whether the region is an ascending region or a descending region based on the change in the feature amount in the period of the plurality of frames in the region. The rising region is a region where the brightness of the image is rising during the period of the plurality of frames, and the decreasing region is a region where the brightness of the image is decreasing during the period of the plurality of frames. And the area estimation part 3 estimates a movement destination area | region and a loss | disappearance area | region based on the determination result of a raise area | region and a fall area | region.

Specifically, the region estimation unit 3 calculates a feature amount difference between the two frames for each divided region. In the present embodiment, as a difference, a value obtained by subtracting the feature amount of the frame immediately before the display frame from the feature amount of the frame immediately before the display frame is calculated. The area estimation unit 3 determines a divided area having a positive difference as a rising area, and determines a divided area having a negative difference as a falling area.
Then, the area estimation unit 3 assigns “+” to the divided area determined as the rising area, “−” to the divided area determined as the falling area, and “0” to the other divided areas. An assigned difference determination result map is generated.
In addition, since the difference mentioned above depends on the motion of an image, it can also be said that the process which produces | generates a difference judgment result map is a process which judges the motion of an image (movement of a moving body).

Next, the region estimation unit 3 generates a control value correction map using the difference determination result map.
In the present embodiment, it is assumed that the brightness of the image in the area of the moving body is higher than the brightness of the image in the other areas.
The area estimation unit 3 estimates a divided area determined as an ascending area as a movement destination area, and estimates a divided area determined as a lowered area as a lost area.
In addition, the area estimation unit 3 estimates, as a movement destination area, a divided area in which the number of surrounding rising areas is equal to or more than the number of surrounding falling areas among the divided areas that are not determined to be the rising area or the falling area. Then, the area estimation unit 3 estimates a divided area in which the number of surrounding lowered areas is larger than the number of surrounding raised areas among the divided areas that are not determined as the ascending area or the lowered area as the disappearing area. In the present embodiment, eight divided areas adjacent to the divided area to be estimated are divided into upper, lower, right, left, upper right, lower right, upper left, and lower left areas as divided areas around the estimated divided area. Referenced.
Then, the area estimation unit 3 assigns “1” to the divided area estimated as the movement destination area, assigns “−1” to the divided area estimated as the lost area, and sets “0” to the other divided areas. "Is assigned to the control value correction map. As described above, the control value correction map is sent to the backlight control value correction unit 4.

In this embodiment, the example in which the movement destination area and the disappearance area are estimated using the feature amounts for two frames has been described. However, the present invention is not limited to this. Region estimation may be performed using feature quantities of more than two frames. When the moving speed of the moving body is slow, the moving body may exist in the same divided area in the period of the two frames, and the movement of the moving body (specifically, the rising area and the decreasing area) may not be detected. If a feature amount of more than two frames is used, such a motion can be detected. However, an increase in the number of frames that refer to the feature amount causes an increase in the storage capacity of the storage unit that stores the feature amount, an increase in the processing amount (processing time) of the motion detection process, and the like. Therefore, it is preferable that the number of frames that refer to the feature amount is determined in consideration of the storage capacity and the processing amount.

(Backlight control value correction unit)
The operation of the backlight control value correction unit 4 will be described in detail.
The backlight control value correction unit 4 brings the target luminance of the light source corresponding to the movement destination area close to a value based on the feature amount of the image data in the moving object area. Further, the backlight control value correction unit 4 brings the target luminance of the light source corresponding to the disappearance area close to a value based on the feature amount of the image data in the area other than the moving body area.

As described above, in this embodiment, the brightness of the image in the area of the moving object is higher than the brightness of the image in the other areas.
Then, the backlight control value correction unit 4 sets the target luminance of the light source corresponding to the movement destination area, which is a divided area to which “1” is assigned, in the control value correction map, the target luminance, and the target of the surrounding light sources. The brightness is corrected to the highest target brightness. Specifically, the backlight control value of the destination area (the backlight control value determined by the backlight control value determination unit 2) is assigned to nine divided areas of 3 rows and 3 columns centered on the destination area. It is corrected to the maximum value of the corresponding nine backlight control values.
Further, the backlight control value correction unit 4 determines the target luminance of the light source corresponding to the disappearance region, which is a divided region to which “−1” is assigned, in the control value correction map, the target luminance, and the target of the surrounding light sources. The brightness is corrected to the lowest target brightness. Specifically, the backlight control value of the lost area (the backlight control value determined by the backlight control value determination unit 2) corresponds to nine divided areas of 3 rows and 3 columns centered on the lost area. It is corrected to the minimum value of the nine backlight control values.

In this embodiment, the highest target luminance is adopted among the target luminance of the light source corresponding to the destination area and the target luminance of the peripheral light sources, and the target luminance of the light source corresponding to the disappearance area is Although the lowest target luminance among the target luminances of the light source is adopted, the present invention is not limited to this. For example, the target luminance of the light source corresponding to the movement destination area may be corrected to an average value of the target luminance and the target luminance of the surrounding light sources. Further, the target luminance of the light source corresponding to the disappearance region may be corrected to an average value of the target luminance and the target luminance of the surrounding light sources. If the target luminance is corrected to the average value, the change in the target luminance between the divided areas can be made smooth.
In this embodiment, an example of correcting the target luminance of the light source (the light source corresponding to the movement destination region or the disappearance region) that is the target of correction of the target luminance based on the target luminance and the surrounding target luminance. As will be described, the target luminance correction method is not limited to this. If the target brightness of the light source corresponding to the destination area is brought close to a value based on the feature quantity of the moving object, and the target brightness of the light source corresponding to the disappearance area is brought close to a value based on the feature quantity other than the moving body, the target The luminance may be corrected in any way.

(Concrete example)
A specific example of the processing (processing result) according to the present embodiment will be described with reference to FIG.
In FIG. 2, t1 to t6 indicate times.
R0 indicates an image (input image) represented by the input image data of the display frame. The input image R0 is an image of one frame in a moving image in which a white object moves from left to right on a black background. In the example of FIG. 2, the white object moves from left to right from time t1 to time t5 and stops moving at time t5. Therefore, the input image is the same for the frame at time t5 and the frame at time t6.
In FIG. 2, the backlight 5 has 35 light sources of 7 in the horizontal direction and 5 in the vertical direction, and 35 areas corresponding to the 35 light sources form the horizontal area constituting the screen area. An example in the case of 35 divided areas of 7 in the direction × 5 in the vertical direction is shown. Note that the grid shown in the input image R0 indicates the boundaries of the divided areas and is not part of the input image R0.

  R1 indicates the feature amount acquired by the feature amount acquisition unit 1. As described above, in this embodiment, it takes time for one frame to acquire the statistics. Therefore, the feature value R1 shown in association with each time indicates the feature value acquired from the input image data of the frame immediately before the display frame. For example, the feature amount R1 corresponding to the time t2 is a feature amount acquired from the data of the input image R0 at the time t1. FIG. 2 shows an example in which the possible pixel values are 0 or more and 255 or less, and the maximum value of the pixel values in the corresponding divided region is acquired as the feature amount R1.

  R2 represents the feature amount acquired from the input image data of the frame immediately before the display frame. A storage unit (not shown) stores the feature amount R1 and the feature amount R2 described above.

  R3 indicates a backlight control value determined using the feature amount R1. FIG. 2 shows that the backlight control value is 1 when the feature amount R1 (maximum pixel value) is 255, and the backlight control value is 0.5 when the feature amount R1 is 0. An example in which is determined is shown.

R4 indicates a difference determination result map generated using the difference between the feature amount R1 and the feature amount R2.
R5 indicates a control value correction map generated using the difference determination result map R4.
R6 indicates a backlight control value obtained by correcting the backlight control value R3 using the control value correction map R5.

R7 indicates a lighting state of a plurality of light sources according to the backlight control value R3, that is, a conventional lighting state.
R8 indicates a lighting state of a plurality of light sources according to the backlight control value R6, that is, a lighting state according to the present embodiment.
In the lighting states R7 and R8, the divided area corresponding to the light source turned on with the backlight control value 1 is shown in white, and the divided area corresponding to the light source turned on with the backlight control value 0.5 is shown with dots. In the lighting states R7 and R8, white objects are superimposed.

The maximum pixel value of the white object is 255. Therefore, it is desirable that the light source in the white object region is lit with a backlight control value of 1.
However, as can be seen from the lighting state R7, in the conventional method, the light source corresponding to the divided area where the white object exists may be turned on with the backlight control value 0.5 (time t3, t4). Therefore, in the conventional method, the backlight luminance (luminance of light from the backlight 5) with respect to the white object region is insufficient, and the white object may be displayed darkly.
On the other hand, as can be seen from the lighting state R8, in this embodiment, the light source corresponding to the divided area where the white object exists can always be lit with the backlight control value 1, and the white object is displayed with a desired luminance. Can do. In this embodiment, when there is no image movement, the light source can be turned on as in the conventional method. Specifically, only the light source corresponding to the white object can be turned on with the backlight control value 1, and the occurrence of black float can be suppressed.

FIG. 3 shows another example of input image data. FIG. 3 shows an example in which the input image data is moving image data in which a white oval object moves from left to right on a black background and a white circular object moves from top to bottom on a black background. Indicates. The elliptical object and the circular object move so as to intersect each other.
The meaning of the information indicated by the symbols R1 to R8 is the same as in the example of FIG.
Also in the example of FIG. 3, as can be seen from the lighting state R7, in the conventional method, the light source corresponding to the divided area where the white object (elliptical object, circular object) exists is turned on with the backlight control value 0.5. (Time t3 to t5). Therefore, in the conventional method, the backlight luminance (luminance of light from the backlight 5) with respect to the white object region is insufficient, and the white object may be displayed darkly.
On the other hand, as can be seen from the lighting state R8, in this embodiment, the light source corresponding to the divided area where the white object exists can always be lit with the backlight control value 1, and the white object is displayed with a desired luminance. Can do.

Further, as shown in the lighting state R7 at time t4, in the conventional method, the light source corresponding to the fourth divided region from the left and the third divided region from the top (the divided region where the moving body is not displayed) is the backlight control value 1. Is lit. Therefore, black floating occurs in the fourth divided area from the left and the third divided area from the top.
On the other hand, as shown in the lighting state R7 at time t4, in this embodiment, the light sources corresponding to the fourth divided region from the left and the third divided region from the top are turned on with the backlight control value 0.5. Therefore, it is possible to suppress the occurrence of black floating in the fourth divided region from the left and the third divided region from the top.

As described above, according to the present embodiment, the destination area is estimated, and the target luminance of the light source corresponding to the estimated destination area is corrected. Thereby, the light emission luminance of each light source can be controlled to an appropriate value. Specifically, it is possible to compensate for the delay in controlling the light emission luminance in the area of the moving object. In this embodiment, since the display frame is not delayed, the light emission luminance of each light source can be controlled to an appropriate value without delaying the display of the image.
Further, according to the present embodiment, the disappearance area is further estimated, and the target luminance of the light source corresponding to the estimated disappearance area is further corrected. Thereby, also in the area other than the area of the moving body, it is possible to compensate for the delay in the control of the light emission luminance, and to control the light emission luminance of the light source to an appropriate value.

  In FIGS. 2 and 3, the pixel values of the input image data are assumed to be binary (0 and 255) for the sake of simplicity, but the pixel values of the input image data are not limited to these. The pixel value of the input image data may be any value as long as it is within the range of values that the pixel value can take. When the transmittance increases linearly with respect to the increase in pixel value, the backlight control value is set so that the backlight control value increases linearly with respect to the increase in the feature amount (maximum pixel value). Just decide.

  In the present embodiment, an example has been described in which eight divided areas adjacent to a noticed divided area (target area) are referred to as divided areas around the noticed area. However, the present invention is not limited to this. For example, the number of peripheral divided regions may be more or less than eight. Specifically, the preferred number of divided areas to be referred to as the peripheral divided areas depends on the size of the divided areas. When the divided area size is small, more divided areas are divided into the peripheral divided areas than when the divided area is large. Reference is preferably made to a region. Thereby, the delay in the control of the light emission luminance can be compensated with higher accuracy.

In the present embodiment, the process of acquiring the feature amount and determining the motion of the image is performed for each divided region (region corresponding to the light source). However, the present invention is not limited to this. For example, for each finely divided area obtained by dividing the screen more finely than the divided area, a process of acquiring the feature amount and determining the motion of the image may be performed. Then, the motion determination result for each divided region may be obtained from the motion determination result for each subdivided region, and the target luminance for each divided region may be corrected. In this case, since the number of statistics to be acquired increases, the feature capacity storage capacity, the feature quantity acquisition, and the motion determination processing volume increase. However, since the movement can be determined in units of small areas, the movement of the moving body can be determined with higher accuracy. As a result, it is possible to compensate for the delay in controlling the light emission luminance with higher accuracy and to suppress the occurrence of black float with higher accuracy.

  In this embodiment, the example in which not only the destination area but also the lost area is estimated has been described, but the lost area may not be estimated. Only the destination area may be estimated, and only the target luminance of the light source corresponding to the destination area may be corrected. Thereby, the delay of the light emission luminance of the light source in the area of the moving body can be compensated, and the moving body can be displayed with a desired luminance.

  In this embodiment, the example in which the brightness of the image in the area of the moving object is brighter than the brightness of the image in the other area has been described, but the present invention is not limited to this. The brightness of the image in the area of the moving object may be darker than the brightness of the image in the other area. In that case, the divided area determined to be the lowered area may be estimated as the movement destination area, and the divided area determined to be the raised area may be estimated as the lost area. In addition, among the divided areas that are not determined to be the rising area or the falling area, a divided area in which the number of the surrounding falling areas is equal to or more than the number of the surrounding rising areas is estimated as the movement destination area, and the number of the surrounding rising areas is What is necessary is just to estimate the division area more than the number of surrounding fall areas as a loss | disappearance area | region.

<Example 2>
Hereinafter, a display device and a control method thereof according to Embodiment 2 of the present invention will be described. In the first embodiment, the example in which the movement destination area is estimated using the difference in the feature amount between the frames has been described. In the present embodiment, an example will be described in which a motion vector is detected and a destination area is estimated using the detected motion vector.

(overall structure)
The overall configuration of the liquid crystal display device according to this example is the same as that of Example 1 (FIG. 1).
However, in the present embodiment, the processes of the region estimation unit 3 and the backlight control value correction unit 4 are different from those in the first embodiment.

(Area estimation unit and backlight control value correction unit)
The region estimation unit 3 detects, for each divided region, a motion vector that represents the motion of the image in the divided region based on the change in the feature amount during a plurality of frames N frames or more before the display frame. In the present embodiment, as in the first embodiment, N = 1, and the plurality of frames are two frames (one frame before the display frame and two frames before the two display frames). Hereinafter, the frame immediately before the display frame is referred to as “first previous frame”, and the frame immediately before the display frame is referred to as “second previous frame”.

In this embodiment, a plurality of divided areas are selected in order as the attention area. Then, the area of the image of the second previous frame similar to the image of the first previous frame in the area consisting of nine divided areas of 3 rows and 3 columns centering on the attention area (consisting of 9 divided areas of 3 rows and 3 columns). Region) is detected by block matching. Specifically, an area where the SAD value, which is the sum of absolute values of differences (differences in feature amounts between the two frames) for each of the nine divided areas, is minimum is detected by block matching. Then, a vector from the corresponding area to the attention area, which is a divided area at the center of the nine divided areas constituting the detected area, is calculated as a motion vector corresponding to the attention area. However, when the minimum value of the SAD value is larger than the predetermined value or when a plurality of regions where the SAD value is minimum is detected, it is determined that there is no motion vector for the attention region. At the edge of the screen, block matching is performed using divided regions such as 1 row 3 columns, 2 rows 3 columns, 3 rows 2 columns, 3 rows 1 columns, and the like.
The motion vector detection method is not limited to the method described above. If a motion vector is detected based on the feature amount, the motion vector may be detected in any way.

The backlight control value correction unit 4 estimates the movement destination region based on the motion vector detected by the region estimation unit 3.
Then, the backlight control value correction unit 4 corrects the target luminance based on the estimation result of the movement destination area.
The destination area may be estimated by the area estimation unit 3.

(Concrete example)
A specific example of the processing (processing result) according to the present embodiment will be described with reference to FIG.
R0, R1, and R2 in FIG. 4 are the same as R0, R1, and R2 in FIG. 3, respectively. 4 is the same as R7 in FIG.

  R9 indicates a motion vector for each divided region detected by the method described above. In FIG. 4, “−” is described in the divided area determined as “no motion vector”. Information indicating a corresponding motion vector is described in a motion region that is a split region where an image moves (that is, a split region in which a motion vector is detected). Specifically, in the motion area (the divided area corresponding to the end point of the detected motion vector), the positional shift amount (x, y) from the motion area to the divided area corresponding to the start point of the motion vector is described. Has been. x is the amount of deviation in the horizontal direction, and y is the amount of deviation in the vertical direction. The shift amount x = −A indicates that the horizontal position of the start point of the motion vector is shifted leftward from the horizontal position of the end point by A divided areas. The shift amount x = A indicates that the horizontal position of the start point of the motion vector is shifted rightward from the horizontal position of the end point by A divided areas. The shift amount y = −B indicates that the vertical position of the start point of the motion vector is shifted upward by B divided areas from the vertical position of the end point. The shift amount y = B indicates that the vertical position of the start point of the motion vector is shifted downward by B divided areas from the vertical position of the end point.

  It is considered that the image in the motion area moves further in the direction according to the motion vector of the motion area in the display frame. In the present embodiment, it is considered that the image in the divided area in which the deviation amount (x, y) is described moves to the position of the deviation amount (−x, −y) from the divided area in the display frame. Further, in this embodiment, the motion vector is detected using the attention area and the surrounding divided areas (the divided area of 3 rows and 3 columns centering on the attention area). Therefore, it is considered that the image in the divided region around the motion region is further moved in the direction according to the motion vector of the motion region in the display frame.

  Therefore, in the present embodiment, the backlight control value correction unit 4 estimates the area at the position indicated by the motion vector of the motion area starting from the position of the motion area as the movement destination area. In addition, the backlight control value correction unit 4 further estimates a region at the position indicated by the motion vector of the motion region starting from the position of the peripheral region that is the peripheral region of the motion region as a destination region. To do. In the present embodiment, the peripheral area is eight divided areas adjacent to the motion area at the upper, lower, right, left, upper right, lower right, upper left, and lower left.

In this embodiment, the backlight control value correction unit 4 sets the target luminance of the light source corresponding to the destination area at the position indicated by the motion vector of the motion area to the area at the start position of the motion vector. Correction is made based on the target luminance.
Specifically, in the present embodiment, as in the first embodiment, the brightness of the image in the area of the moving object is higher than the brightness of the image in the other areas. Then, the backlight control value correction unit 4 has the light source target luminance corresponding to the movement destination region at the position indicated by the motion vector of the motion region, and the light source target corresponding to the region at the start point position of the motion vector. When the brightness is lower than the brightness, the target brightness of the light source corresponding to the movement destination area is corrected to the target brightness of the light source corresponding to the area at the start point position.
In FIG. 4, R10 represents a backlight control value obtained by correcting the backlight control value R3 based on the motion vector detection result R9.

  FIG. 5 shows a schematic diagram of the process for estimating the destination area and the process for correcting the target brightness. FIG. 5 is an excerpt of part of FIG. 4 (part of R3, part of R9, and part of R10 at time t3). Hereinafter, the process of estimating the movement destination area and the process of correcting the target luminance will be described in detail, paying attention to the divided area in the y2 row x2 column. As shown in R9 of FIG. 5, the motion region in which the motion vector having the segmented region in the y1 row x1 column as the start point and the segmented region in the y2 row x2 column as the end point is detected in the segmented region in the y2 row x2 column. It is an area. For this reason, nine divided regions (regions indicated by broken lines in R9) centered on the divided region of y2 row x2 column are moved to the right and one down by nine divided regions (regions indicated by broken lines of R9) ( The area indicated by the thick solid line of R9) is estimated as the destination area. Then, when the target luminance R3 of the destination divided region is lower than the target luminance R3 of the source divided region, the target luminance R3 of the destination divided region is replaced with the target luminance R3 of the source divided region, It is set as the target luminance R10 after correction. For example, the target luminance R3 = 0.5 of the divided region in the y2 row x4 column is the target luminance of the divided region in the y1 row x3 column that is the moving source divided region (one left, one above the divided region). R3 = 1 is lower. Therefore, the corrected target luminance R10 of the divided area of y2 row x4 column is corrected to 1 (target luminance R3 = 1 of the divided area of y1 row x3 column). Similarly, the target luminance R10 is corrected to 1 for the divided region in the y2 row x4 column and the divided region in the y2 row x4 column. For the remaining six divided regions, the target luminance R10 is set to the same value as the target luminance R3.

  R11 indicates a lighting state of a plurality of light sources according to the backlight control value R10, that is, a lighting state according to the present embodiment. As can be seen from the lighting state R11, in this embodiment, the light source corresponding to the divided area where the white object (elliptical object, circular object) exists can always be lit with the backlight control value 1, and the white object is desired. It is possible to display with the brightness. In this embodiment, it is possible to accurately determine the motion of an image by detecting a motion vector. Therefore, as can be seen from the lighting state R11, compared to the first embodiment, it is possible to reduce the number of divided areas (divided areas where no white object is present) that is erroneously estimated as the movement destination area, and the occurrence of black floating, etc. Image quality degradation can be reduced.

  As described above, according to the present embodiment, a motion vector is detected based on a change in a feature amount during a plurality of frames, a destination area is estimated based on the detected motion vector, and a destination area The target luminance of the light source corresponding to is corrected. Thereby, compared with Example 1, a movement destination area | region can be estimated with a sufficient precision, and the light emission luminance of each light source can be more reliably controlled to an appropriate value.

  In this embodiment, the region at the position indicated by the motion vector of the motion region starting from the position of the peripheral region that is the peripheral region of the motion region is further estimated as the destination region. However, such a process may not be performed. If such a process is performed, the delay of the light emission luminance with respect to the moving body can be reduced more accurately. However, even if only the region at the position indicated by the motion vector of the motion region starting from the position of the motion region is estimated as the destination region, the emission luminance delay with respect to the moving object is reduced compared to the conventional case. Can be reduced.

<Other examples>
The present invention can also be implemented by a system (or a device such as a CPU or MPU) of a system or apparatus that implements the functions of the above-described embodiments by reading and executing a program recorded in a storage device. The present invention can also be implemented by a method comprising steps executed by a computer of a system or apparatus that implements the functions of the above-described embodiments by reading and executing a program recorded in a storage device, for example. . For this purpose, the program is stored in the computer from, for example, various types of recording media that can serve as the storage device (ie, computer-readable recording media that holds data non-temporarily). Provided to. Therefore, the computer (including devices such as CPU and MPU), the method, the program (including program code and program product), and the computer-readable recording medium that holds the program non-temporarily are all present. It is included in the category of the invention.

DESCRIPTION OF SYMBOLS 1 Feature-value acquisition part 2 Backlight control value determination part 3 Area | region estimation part 4 Backlight control value correction | amendment part 5 Backlight 7 Liquid crystal panel 9 Control part

Claims (33)

A light emitting means having a plurality of light sources capable of individually controlling the light emission brightness;
A display panel that displays an image on a screen by modulating light from the light emitting means;
Control means for controlling the light emission luminance of each light source according to the brightness of the image to be displayed in the area on the screen corresponding to each of the plurality of light sources;
In a display device having
For each of a plurality of regions corresponding to the plurality of light sources, the control means sets a feature amount representing the brightness of an image to be displayed in the region N frames before the display frame (N is an integer of 1 or more). The target luminance of the light source corresponding to each area is determined based on the acquired feature amount of each area.
The control means includes
A moving destination that is a region where a moving body existing in the image before N frames can move in the image of the display frame based on a change in feature amount in a period of a plurality of frames N frames or more before the display frame An estimation means for estimating a region;
Correction means for correcting the target luminance of the light source corresponding to the destination area estimated by the estimation means;
A display device comprising: The display device according to claim 1, further comprising storage means for storing feature quantities for the plurality of frames. The estimation means includes
Based on the change of the feature amount in the period of the plurality of frames, determine the movement of the moving body in the period of the plurality of frames,
The display device according to claim 1, wherein the destination area is estimated based on the determined movement of the moving body. The estimation means includes
For each of the regions corresponding to the light source, based on the change in the feature amount of the region in the period of the plurality of frames, the region is a rising region in which the brightness of the image is increased in the period of the plurality of frames, Determining whether the brightness of the image has decreased in the period of the plurality of frames,
The display device according to claim 1, wherein the destination area is estimated based on a determination result of the ascending area and the descending area. The brightness of the image in the area of the moving object is higher than the brightness of the image in the other areas,
The estimation means includes
An area determined to be an ascending area;
Of the areas that are not determined as rising areas or falling areas, the number of surrounding rising areas is equal to or greater than the number of surrounding falling areas;
The display apparatus according to claim 4, wherein the movement destination area is estimated. The estimation means includes
Detecting a motion vector representing the motion of an image in the region for each region corresponding to the light source based on a change in a feature amount in a period of the plurality of frames;
The display device according to claim 1, wherein the destination area is estimated based on the detected motion vector. The estimation unit estimates a region at a position indicated by a motion vector of the motion region as a destination region, starting from a position of the motion region that is a region where the image moves. Item 7. The display device according to Item 6. The estimation means estimates a region at a position indicated by a motion vector of the motion region, starting from a position of the peripheral region that is a peripheral region of the motion region, as a destination region. The display device according to claim 7. The said correction | amendment means approaches the target brightness | luminance of the light source corresponding to a moving-destination area | region close to the value based on the feature-value of the image data in the area | region of a moving body. Display device. The said correction | amendment means correct | amends the target brightness | luminance of the light source corresponding to a moving-destination area | region based on the said target brightness | luminance and the target brightness | luminance of a surrounding light source. The display device described. The brightness of the image in the area of the moving object is higher than the brightness of the image in the other areas,
The correction means corrects the target luminance of the light source corresponding to the destination area to the highest target luminance among the target luminance and the target luminance of the surrounding light sources. The display device according to any one of the above. The correction means corrects the target luminance of the light source corresponding to the destination area to an average value of the target luminance and the target luminance of the surrounding light sources. The display device described in 1. The correction means corrects the target luminance of the light source corresponding to the destination region at the position indicated by the motion vector of the motion region based on the target luminance of the region at the start point position of the motion vector. The display device according to claim 7 or 8. The brightness of the image in the area of the moving object is higher than the brightness of the image in the other areas,
The correction unit is configured such that when the target luminance of the light source corresponding to the movement destination region at the position indicated by the motion vector of the motion region is lower than the target luminance of the light source corresponding to the region at the start point position of the motion vector. The display device according to claim 7, wherein the target luminance of the light source corresponding to the movement destination area is corrected to the target luminance of the light source corresponding to the area at the start point position. The estimation means is a region where a moving body is present in the image before the N frames, but no moving body is present in the image of the display frame, based on a change in the feature amount in the period of the plurality of frames. Further estimate the disappearance area,
The display device according to claim 1, wherein the correction unit further corrects a target luminance of the light source corresponding to the disappearance region estimated by the estimation unit. The display device according to claim 15, wherein the correction unit brings the target luminance of the light source corresponding to the disappearance region close to a value based on a feature amount of image data in a region other than the region of the moving body. A light emitting means having a plurality of light sources capable of individually controlling the light emission brightness;
A display panel that displays an image on a screen by modulating light from the light emitting means;
A display device control method comprising:
A control step of controlling the light emission luminance of each light source according to the brightness of an image to be displayed in an area on the screen corresponding to each of the plurality of light sources;
In the control step, for each of a plurality of areas corresponding to the plurality of light sources, a feature amount representing the brightness of an image to be displayed in the area is displayed N frames before the display frame (N is an integer of 1 or more). The target luminance of the light source corresponding to each area is determined based on the acquired feature amount of each area.
In the control step,
A moving destination that is a region where a moving body existing in the image before N frames can move in the image of the display frame based on a change in feature amount in a period of a plurality of frames N frames or more before the display frame An estimation step for estimating a region;
A correction step of correcting the target luminance of the light source corresponding to the destination area estimated by the estimation step;
A control method for a display device, comprising: 18. The display device control method according to claim 17, further comprising a storing step of storing the feature amounts for the plurality of frames in a storage unit. In the estimation step,
Based on the change of the feature amount in the period of the plurality of frames, determine the movement of the moving body in the period of the plurality of frames,
19. The display device control method according to claim 17, wherein the destination area is estimated based on the determined movement of the moving body. In the estimation step,
For each of the regions corresponding to the light source, based on the change in the feature amount of the region in the period of the plurality of frames, the region is a rising region in which the brightness of the image is increased in the period of the plurality of frames, Determining whether the brightness of the image has decreased in the period of the plurality of frames,
The method for controlling a display device according to any one of claims 17 to 19, wherein the destination area is estimated based on the determination result of the ascending area and the descending area. The brightness of the image in the area of the moving object is higher than the brightness of the image in the other areas,
In the estimation step,
An area determined to be an ascending area;
Of the areas that are not determined as rising areas or falling areas, the number of surrounding rising areas is equal to or greater than the number of surrounding falling areas;
21. The method of controlling a display device according to claim 20, wherein the movement destination area is estimated. In the estimation step,
Detecting a motion vector representing the motion of an image in the region for each region corresponding to the light source based on a change in a feature amount in a period of the plurality of frames;
The method for controlling a display device according to any one of claims 17 to 19, wherein the destination area is estimated based on the detected motion vector. The estimation step includes estimating a region at a position indicated by a motion vector of the motion region, starting from the position of the motion region that is a region with image motion, as a destination region. Item 23. A control method for a display device according to Item 22. In the estimation step, a region at a position indicated by a motion vector of the motion region starting from the position of the peripheral region that is a region around the motion region is further estimated as a destination region. The method for controlling a display device according to claim 23. 25. The correction step according to any one of claims 17 to 24, wherein in the correction step, the target luminance of the light source corresponding to the movement destination region is brought close to a value based on a feature amount of the image data in the region of the moving body. Display device control method. The correction step corrects the target luminance of the light source corresponding to the destination area based on the target luminance and the target luminance of the surrounding light sources. A control method of the display device described. The brightness of the image in the area of the moving object is higher than the brightness of the image in the other areas,
27. In the correction step, the target luminance of the light source corresponding to the destination area is corrected to the highest target luminance among the target luminance and the target luminance of the surrounding light sources. The control method of the display apparatus of any one. 27. In the correction step, the target luminance of the light source corresponding to the destination area is corrected to an average value of the target luminance and the target luminance of surrounding light sources. The control method of the display apparatus as described in 2. In the correction step, the target luminance of the light source corresponding to the movement destination region at the position indicated by the motion vector of the motion region is corrected based on the target luminance of the region at the start point position of the motion vector. The control method of the display device according to claim 23 or 24. The brightness of the image in the area of the moving object is higher than the brightness of the image in the other areas,
In the correction step, when the target brightness of the light source corresponding to the movement destination area at the position indicated by the motion vector of the motion area is lower than the target brightness of the light source corresponding to the area at the start point position of the motion vector. 25. The method of controlling a display device according to claim 23, wherein the target luminance of the light source corresponding to the movement destination area is corrected to the target luminance of the light source corresponding to the area at the start point position. In the estimation step, a moving body is present in the image before the N frames based on a change in the feature amount during the plurality of frames, but the moving body is not present in the display frame image. Further estimate the disappearance area,
The display device control method according to any one of claims 17 to 30, wherein in the correction step, the target luminance of the light source corresponding to the disappearance region estimated in the estimation step is further corrected. 32. The method of controlling a display device according to claim 31, wherein, in the correcting step, the target luminance of the light source corresponding to the disappearance region is brought close to a value based on a feature amount of image data in a region other than the region of the moving body. . A program for causing a computer to execute each step of the display device control method according to any one of claims 17 to 32.

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