JP7377124B2 - display device - Google Patents

Description

The present invention relates to a display device.

Conventionally, head-mounted displays (Head Mounted Displays, hereinafter also referred to as "HMD") that realize so-called virtual reality images (hereinafter also referred to as "VR") have been designed to capture head movements. A technique is disclosed in which a sensor is provided to detect images and images are displayed according to the movement of the body (for example, Patent Document 1).

Japanese Patent Application Publication No. 6-78248

2. Description of the Related Art Display devices are known that have a local dimming function that divides a light source device such as a backlight into a plurality of regions and controls the light emission of the light source for each region according to the video signal of the divided regions. When a display device equipped with such a local dimming function is used as an HMD display for realizing VR, backlight control follows video signal processing with a delay, and when the viewpoint changes significantly, high brightness areas brightness may be insufficient.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a display device that can suppress delays in backlight control with respect to video signal processing.

A display device according to one embodiment of the present invention is a display device whose display is controlled based on an image signal, and has a light emitting region divided into a plurality of divided light emitting regions, and a display region overlapping the light emitting region. The display device includes a light source device for illuminating, and a signal processing unit that calculates a lighting amount for each of the plurality of divided light emitting regions based on a movement amount of an object on the light emitting region according to a change in the self-position of the display device.

FIG. 1 is a block diagram showing an example of the configuration of a display device according to the first embodiment. FIG. 2 is a conceptual diagram of the image display panel according to the first embodiment. FIG. 3 is a schematic diagram showing a screen display surface of the display device according to the first embodiment. FIG. 4 is a diagram showing a light emitting region of the display device according to the first embodiment. FIG. 5 is a functional block diagram showing an example of the configuration of the signal processing section. FIG. 6 is a functional block diagram showing a configuration example of the lighting amount control section according to the first embodiment. FIG. 7 is a diagram illustrating the coordinates of each divided light emitting area on the light emitting area. FIG. 8 is a diagram illustrating an example of an object movement amount on a light emitting area. FIG. 9 is a diagram showing a first example of a method for calculating the second lighting amount. FIG. 10 is a diagram illustrating a second example of a method for calculating second lighting amount information. FIG. 11 is a functional block diagram showing a configuration example of a lighting amount control section according to a comparative example. FIG. 12 is a functional block diagram showing a configuration example of a lighting amount control section according to the second embodiment. FIG. 13 is a diagram illustrating an example of a threshold value for an object movement amount.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Modes (embodiments) for carrying out the present invention will be described in detail with reference to the drawings. Note that the present invention is not limited to the contents described in the embodiments below. Further, the constituent elements described below include those that can be easily assumed by those skilled in the art and those that are substantially the same. Furthermore, the components described below can be combined as appropriate. Furthermore, the disclosure is merely an example, and any modifications that can be easily made by those skilled in the art while maintaining the gist of the invention are naturally included within the scope of the present invention. In addition, in order to make the explanation clearer, the drawings may schematically represent the width, thickness, shape, etc. of each part compared to the actual aspect, but these are only examples, and the interpretation of the present invention is It is not limited. In addition, in this specification and each figure, the same elements as those described above with respect to the previously shown figures are denoted by the same reference numerals, and detailed explanations may be omitted as appropriate.

(Embodiment 1)
FIG. 1 is a block diagram showing an example of the configuration of a display device according to the first embodiment. FIG. 2 is a conceptual diagram of the image display panel according to the first embodiment. The display device 10 according to the present embodiment is, for example, a liquid crystal display device applied to an HMD (Head Mounted Display) that is mounted on the head of an observer to realize VR (Virtual Reality). The display device 10 displays an image based on position information acquired by a sensor 12 (for example, an acceleration sensor) that detects at least the movement of the head of the image viewer in the left-right direction (X direction) and the up-down direction (Y direction). Displays an image according to the movement of the viewer's head.

As shown in FIG. 1, the display device 10 according to the first embodiment includes a signal processing section 20, an image display panel 40, and a light source unit 60 (light source device). The image display panel 40 includes an image display panel drive section 30 and a display section 33.

The signal processing section 20 applies predetermined data conversion processing to the input image signal according to the input image signal (RGB data) and position information from the control device 11 and sends a generated signal to each section of the display device 10 .

The image display panel driving section 30 controls the driving of the display section 33 based on the signal from the signal processing section 20.

The light source unit 60 illuminates a display area 41 provided in the display section 33 of the image display panel 40 from the back side.

The image display panel 40 displays an image using a signal from the image display panel drive section 30 and light from the light source unit 60.

To explain with a more specific example, the image display panel 40 displays a frame image for displaying an image in the display area 41 in one frame period. In the first embodiment, input image signals indicating the RGB gradation values of each of a plurality of pixels constituting one frame image are input as a unit to the signal processing unit 20 within a predetermined period.

The signal processing unit 20 outputs a pixel signal and a light source drive signal based on the input image signal so that a frame image is displayed on the image display panel 40 within one predetermined frame period. The light source drive signal is a signal for driving the light source unit 60.

The light source unit 60 operates under the control of the signal processing section 20 according to the light source drive signal, and obtains the brightness necessary for the frame image displayed by the image display panel 40 from the light emitting area 61 having a size corresponding to the display area 41. emit light. The brightness of light required for a frame image is necessary to obtain the brightness that corresponds to the gradation value of all pixels or multiple pixels related to the display of one screen's worth of input signals that are the source of the frame image. It is a bright light.

In order to obtain light with the brightness necessary for the frame image, the signal processing unit 20 performs a dimming process that uniformly adjusts the light of the entire light emitting area 61 or a local process that adjusts the light from the light emitting area 61 in units of a plurality of divided light emitting areas. Perform dimming processing.

In the display section 33, a plurality of pixels 48 are arranged in a two-dimensional matrix in a display area 41. In this way, the display section 33 functions as a display section having a plurality of pixels 48. The example shown in FIG. 1 shows an example in which a plurality of pixels 48 are arranged in a matrix in an XY two-dimensional coordinate system. In this example, the X direction is the row direction and the Y direction is the column direction, but the present invention is not limited thereto, and the X direction may be the vertical direction and the Y direction may be the horizontal direction.

As shown in FIG. 2, the pixel 48 includes at least two of a first sub-pixel 49R, a second sub-pixel 49G, and a third sub-pixel 49B. The first sub-pixel 49R displays a first color (for example, red). The second sub-pixel 49G displays a second color (for example, green). The third sub-pixel 49B displays a third color (for example, blue). The first color, second color, and third color are not limited to red, green, and blue, and may be complementary colors, as long as they are different from each other. In the following, when there is no need to distinguish between the first sub-pixel 49R, the second sub-pixel 49G, and the third sub-pixel 49B, they will be referred to as sub-pixels 49. That is, one sub-pixel 49 is assigned one of the three colors.

The image display panel 40 of the first embodiment is, for example, a transmissive color liquid crystal display panel. In the display area 41 of the display unit 33, a first color filter that allows the first color to pass is arranged between the first sub-pixel 49R and the image viewer. Further, in the display area 41 of the display unit 33, a second color filter is arranged between the second sub-pixel 49G and the image viewer and allows the second color to pass therethrough. Further, in the display area 41 of the display unit 33, a third color filter is arranged between the third sub-pixel 49B and the image viewer and allows a third color to pass therethrough.

The image display panel drive section 30 includes a signal output circuit 31 and a scanning circuit 32. The image display panel driving section 30 holds the output signals by the signal output circuit 31 and sequentially outputs them to the display section 33. More specifically, the signal output circuit 31 outputs an image signal having a predetermined potential according to the output signal from the signal processing section 20 to the display section 33. The signal output circuit 31 is electrically connected to the display section 33 by a signal line DTL. The scanning circuit 32 controls ON/OFF of a switching element for controlling the operation (light transmittance) of the sub-pixel 49 in the display section 33. The switching element is, for example, a thin film transistor (TFT). The scanning circuit 32 is electrically connected to the display section 33 by a scanning line SCL.

The light source unit 60 is arranged on the back side of the image display panel 40. The light source unit 60 illuminates the image display panel 40 by irradiating light toward the image display panel 40.

FIG. 3 is a schematic diagram showing a screen display surface of the display device according to the first embodiment. The display area 41 is divided into a plurality of divided display areas 42 . As an example, in the display area 41 divided into eight equal parts along the X direction and four equal parts along the Y direction, 800 pieces in the X direction and 480 pieces in the Y direction, that is, 800×480 When the pixels 48 are arranged in a matrix, one divided display area 42 has 100×120 pixels 48. The example of division of the display area 41 and the number of pixels in the display area 41 are just examples, and are not limited to these, and can be changed as appropriate.

FIG. 4 is a diagram showing a light emitting region of the display device according to the first embodiment. In FIG. 4, a divided light emitting area 62 is provided in the light emitting area 61, facing the divided display area 42 of the display area 41 shown in FIG. That is, the light emitting area 61 overlaps the display area 41, and each divided light emitting area 62 of the light emitting area 61 overlaps each divided display area 42 of the display area 41, respectively.

Further, FIG. 4 shows an example in which one light source 63 is arranged at the center of each divided light emitting region 62. The light source 63 is, for example, a light emitting diode (LED), but this is an example of a specific configuration of the light source 63 and is not limited to this, and can be changed as appropriate. 4 shows an example in which one light source 63 is arranged at the center of each divided light emitting area 62 facing each divided display area 42 of the display area 41 shown in FIG. As long as the amount of lighting can be individually controlled and the amount of lighting for each divided light emitting area 62 can be controlled, the configuration is not limited to this and can be changed as appropriate. Specifically, for example, a plurality of light sources 63 may be arranged in each divided light emitting region 62.

Next, the signal processing section 20 will be explained. FIG. 5 is a functional block diagram showing an example of the configuration of the signal processing section. The signal processing section 20 includes a lighting amount control section 21, a light source driving section 22, a brightness distribution calculation section 23, and a pixel processing section 24.

The lighting amount control unit 21 generates the lighting amount for each divided light emitting area 62 based on the input image signal input from the control device 11 and the position information of the display device 10, and generates the lighting amount for each divided light emitting area 62. A light source control signal BL including 62 lighting amount information is generated.

The light source drive unit 22 generates a light source drive signal for driving each light source 63 of each divided light emitting region 62 based on the light source control signal BL output from the lighting amount control unit 21. The light source driving unit 22 adjusts the current value supplied to each light source 63, thereby adjusting the amount of light (light intensity) irradiating the image display panel 40 to the amount of light according to the light source control signal BL.

The brightness distribution calculation unit 23 calculates the brightness distribution of the entire light source unit 60 based on the lighting amount information BB of each divided light emitting region 62 included in the light source control signal BL. Specifically, the brightness distribution calculation unit 23 obtains the same data as the reference data stored in advance in the storage unit of the brightness distribution calculation unit 23, using an algorithm already implemented in the brightness distribution calculation unit 23, or the like. The brightness distribution calculation unit 23 outputs brightness distribution information BM indicating this brightness distribution to the pixel processing unit 24.

The pixel processing unit 24 calculates the gradation value of the pixel 48 for display output based on the unprocessed signal BD with the brightness distribution indicated by the brightness distribution information BM. Specifically, the pixel processing unit 24 corrects the gradation value of each sub-pixel 49 forming the pixel 48 included in each partial area based on the brightness distribution information BM output from the brightness distribution calculation unit 23.

Hereinafter, the lighting amount control section 21 according to this embodiment will be explained with reference to FIGS. 5 to 11.

FIG. 6 is a functional block diagram showing a configuration example of the lighting amount control section according to the first embodiment.

As shown in FIG. 6, the lighting amount control section 21 includes a first lighting amount calculation section 211, a movement amount detection section 212, a second lighting amount calculation section 213, a lighting amount setting section 214, and a storage section 215.

The first lighting amount calculation unit 211 calculates the first lighting amount Es of each divided light emitting region 62 for each frame based on the input image signal.

Specifically, the first lighting amount calculation unit 211 calculates the brightness of each pixel 48 included in each divided light emitting region 62. Here, as an example, a case will be described in which each color of the sub-pixel 49 is represented by an 8-bit gradation value.

The 8-bit gradation value can be expressed as a numerical value with "0" as the minimum value and "255" as the maximum value. In this embodiment, for example, when the gradation value of the second sub-pixel 49G is "255", the brightness of the pixel 48 including the second sub-pixel 49G is set to 100[%]. Further, for example, the gradation value of the second sub-pixel 49G is "127", and the gradation value of the first sub-pixel 49R and the third sub-pixel 49B included in the pixel 48 including the second sub-pixel 49G is " 127'', the brightness of the pixel 48 including the second sub-pixel 49G is set to 50%. That is, among the gradation values of the sub-pixel 49 included in the pixel 48, the brightness corresponding to the maximum gradation value is set as the brightness of the pixel 48. The relationship between the gradation value and brightness of the sub-pixel 49 can be calculated using, for example, table-format data or an arithmetic expression.

The first lighting amount calculation unit 211 calculates the brightness of each pixel 48 included in the divided display area 42 corresponding to each divided light emitting area 62. The first lighting amount calculation unit 211 derives the brightness of the pixel 48 with the highest calculated brightness among all the pixels 48 included in each divided display area 42 as the brightness in the divided display area 42 . Then, the brightness in the divided display area 42 is set as the first lighting amount Es in the divided light emitting area 62 corresponding to the divided display area 42, and the first lighting amount information BB1 including the first lighting amount Es of each divided light emitting area 62 is set. Output.

The movement amount detection unit 212 detects the movement amount of the object on the light emitting area 61 (hereinafter also referred to as "object movement amount") based on the position information of the display device 10 input from the control device 11, and detects the object movement. Output as quantity information MD. In this embodiment, the object on the light emitting area 61 corresponds to an object (for example, a person or an object) displayed within the display image. Further, the amount of object movement corresponds to the amount of movement of the displayed image per predetermined unit time in response to a change in the self-position of the display device 10 (that is, for example, movement of the head of an image viewer wearing an HMD). .

FIG. 7 is a diagram illustrating the coordinates of each divided light emitting area on the light emitting area. FIG. 8 is a diagram illustrating an example of an object movement amount on a light emitting area. In FIG. 7, the center of each divided light emitting region 62 on the light emitting region 61 is indicated by a black dot. Further, in this embodiment, the distance between the divided light emitting regions 62 is normalized as “1”, and the coordinates of the center of each divided light emitting region 62 are used as the coordinates of each divided light emitting region 62. In the example shown in FIG. 7, the coordinates of the divided light emitting region 62 at the upper left in the figure are [m, n]. In the following description, as shown in FIG. 4, an example will be described in which one light source 63 is arranged at the center of each divided light emitting region 62 (coordinates of the black point shown in FIG. 7). That is, in the following description, the center coordinates of the divided light emitting regions 62 correspond to the coordinates where the light sources 63 of the divided light emitting regions 62 are arranged, and the lighting amount in each divided light emitting region 62 corresponds to the center coordinates of each divided light emitting region 62. This corresponds to the amount of lighting of the light source 63 placed in .

In this embodiment, as shown in FIG. 8, the object movement amount in the X direction on the light emitting area 61 per predetermined unit time is Vx, and the object movement amount in the Y direction on the light emitting area 61 per predetermined unit time is Vx. It is set to Vy. At this time, the object movement vector V on the light emitting area 61 per predetermined unit time can be expressed by the following equation (1). Hereinafter, the amount of object movement Vx in the X direction on the light emitting area 61 per predetermined unit time will also be simply referred to as "object movement amount Vx", and the amount of object movement Vy in the Y direction on the light emitting area 61 per predetermined unit time. is also simply referred to as "object movement amount Vy."

V=(Vx, Vy)...(1)

FIG. 8 shows an example in which the object movement amount Vx is "2" and the object movement amount Vy is "-3". Note that, here, in order to simplify the explanation, an example is shown in which the object movement amounts Vx and Vy are each integer values, but the object movement amounts Vx and Vy may also take decimal values.

The second lighting amount calculation unit 213 calculates the second lighting amount Em according to the object movement amount Vx, Vy on the light emitting area 61, and provides second lighting amount information including the second lighting amount Em of each divided light emitting area 62. Output as BB2.

FIG. 9 is a diagram showing a first example of a method for calculating the second lighting amount. FIG. 9 shows an example in which the object movement vector V on the light emitting area 61 is (Vx, Vy)=(0.75, −1.5). Hereinafter, the first lighting amount in each divided light emitting region 62 at the coordinates [x, y] is assumed to be Es[x, y], and the second lighting amount is assumed to be Em[x, y]. x and y are variables.

Here, an example will be described in which the second lighting amount Em[i,j] in the divided light emitting region 62 at the coordinates [i,j] is determined.

The second lighting amount Em[i,j] in the divided light emitting area 62 at the coordinates [i,j] is the coordinate [Xr, Yr] (second coordinate) before moving to the coordinate [i,j] (first coordinate). ) corresponds to the brightness at In other words, the second lighting amount Em[i,j] in the divided light emitting region 62 at the coordinates [i,j] (first coordinates) is the same as the second lighting amount Em[i,j] at the coordinates [Xr, Yr] (first coordinates) before moving to the coordinates [i,j]. 2 coordinates) is expressed as Es[Xr, Yr], it can be expressed by the following equation (2).

Em[i,j]=Es[Xr,Yr]...(2)

Moreover, the coordinates [Xr, Yr] (second coordinates) before moving to the coordinates [i, j] (first coordinates) can be expressed by the following equation (3).

[Xr, Yr]=[i-Vx,j-Vy]...(3)

The brightness at the coordinates [Xr, Yr] (second coordinates), that is, the second lighting amount Em[i, j] in the divided light emitting area 62 at the coordinates [i, j] (first coordinates) is, for example, , j] (first coordinates) is in an area surrounded by a triangle connecting three mutually adjacent coordinates. It can be calculated by the weighted average of each lighting amount (three-point interpolation). Specifically, the brightness at the coordinates [Xr, Yr] (= [i-0.75, j+1.5]) in the example shown in FIG. 9, that is, the second lighting at the coordinates [i, j] (first coordinates) The amount Em [i, j] is the first lighting amount Esa at the coordinates [Xa, Ya] (= [i-1, j-1]), the first lighting amount Esa at the coordinates [Xb, Yb] (= [i-1, j-2 ]) and the first lighting amount Esb at the coordinates [Xc, Yc] (=[i, j-2]), it is expressed by the weighted average value shown in equation (4) below. .

Es[Xr, Yr]=Esa
+(Esb-Esa)×{(Yr-Ya)/(Yb-Ya)}
+(Esc-Esb)×{(Xr-Xb)/(Xc-Xb)}...(4)

As described above, the second lighting amount Em[i,j] at the coordinates [i,j] (first coordinates) is equal to the second lighting amount Em[i,j] at the coordinates [Xr, Yr] before moving to the coordinates [i,j] (first coordinates). ] (second coordinate). That is, the second lighting amount Em[i,j] at the coordinates [i,j] (first coordinates) can be expressed by the following equation (5).

Em[i,j]=Es[Xr,Yr]=Esa
+(Esb-Esa)×{(Yr-Ya)/(Yb-Ya)}
+(Esc-Esb)×{(Xr-Xb)/(Xc-Xb)}...(5)

In this embodiment, as described above, the center coordinates of the divided light emitting regions 62 correspond to the coordinates where the light sources 63 of the divided light emitting regions 62 are arranged, and the lighting amount in each divided light emitting region 62 is corresponds to the lighting amount of the light source 63 located at the center coordinates of . Here, the first lighting amount Es of the three coordinates when calculating the weighted average value using the above formula (5) is determined by This corresponds to the first lighting amount Es in the area 62. In other words, when the three coordinates used to calculate the weighted average value are the center coordinates of each divided light emitting region 62, the first lighting amount Es in each of these divided light emitting regions 62 is used to calculate the coordinates [i, j] (the first It is possible to calculate the second lighting amount Em[i,j] in the light source 63 arranged at the divided light emitting region 62 whose center coordinate is the coordinate [i,j] (first coordinate).

Note that when the object movement amounts Vx and Vy are both integer values, the second lighting amount Em[i,j] in the divided light emitting area 62 whose center coordinates are coordinates [i,j] (first coordinates) is The first lighting amount in the divided light emitting area 62 whose center coordinates are the coordinates [Xr, Yr] (second coordinates) before moving to [i, j] (first coordinates) is applied.

Specifically, for example, when the object movement vector V = (Vx, Vy) = (1, -1), the coordinates [Xr, Yr] before moving to the coordinates [i, j] (first coordinates) (second coordinates) overlaps the coordinates [Xa, Ya]. At this time, the above equation (5) can be expressed as the following equation (6).

Em[i,j]=Es[Xa,Ya]=Esa...(6)

That is, when the object movement vector V = (Vx, Vy) = (1, -1), the second lighting amount Em[ i, j], the first lighting amount Esa in the divided light emitting area 62 having the center coordinates [Xa, Ya] is applied.

Also, for example, when the object movement vector V = (Vx, Vy) = (1, -2), the coordinates [Xr, Yr] (second coordinate) before moving to the coordinate [i, j] (first coordinate) The coordinates) overlap the coordinates [Xb, Yb]. At this time, the above equation (5) can be expressed as the following equation (7).

Em[i,j]=Es[Xb,Yb]=Esb...(7)

That is, when the object movement vector V = (Vx, Vy) = (1, -2), the second lighting amount Em[ i, j], the first lighting amount Esb in the divided light emitting region 62 having the center coordinates [Xb, Yb] is applied.

Also, for example, when the object movement vector V = (Vx, Vy) = (0, -2), the coordinates [Xr, Yr] (second coordinate) before moving to the coordinate [i, j] (first coordinate) The coordinates) overlap the coordinates [Xc, Yc]. At this time, the above equation (5) can be expressed as the following equation (8).

Em[i,j]=Es[Xc,Yc]=Esc...(8)

That is, when the object movement vector V = (Vx, Vy) = (0, -2), the second lighting amount Em[ i, j], the first lighting amount Esc in the divided light emitting region 62 having the center coordinates [Xc, Yc] is applied.

Note that the brightness at the coordinates [Xr, Yr] (=[i-0.75, j+1.5]) in the example shown in FIG. 9, that is, the second lighting amount Em at the coordinates [i, j] (first coordinate) [i, j] is the first lighting amount Esa at the coordinates [Xa, Ya] (= [i-1, j-1]), and the coordinates [Xb, Yb] (= [i-1, j-2]) A weighted average value of the first lighting amount Esb at the coordinates [Xd, Yd] (=[i, j−1]) may be calculated. In addition, without being limited to the above, weighting of the first lighting amount at three or more coordinates adjacent to the coordinates [Xr, Yr] (second coordinates) before moving to the coordinates [i, j] (first coordinates) An embodiment may be adopted in which an average value is calculated and the weighted average value is used as the second lighting amount Em[i,j] at the coordinates [i,j] (first coordinates). In other words, the weighted average value of the first lighting amount at at least three coordinates adjacent to the coordinates [Xr, Yr] (second coordinates) before moving to the coordinates [i, j] (first coordinates) is calculated. However, the weighted average value may be used as the second lighting amount Em[i,j] at the coordinates [i,j] (first coordinates).

FIG. 10 is a diagram illustrating a second example of a method for calculating second lighting amount information. As shown in FIG. 10, if the coordinates (second coordinates) before moving to the coordinates [i, j] (first coordinates) do not exist within the light emitting area 61, the coordinates [i, , j] cannot be calculated. In this case, for example, the second lighting amount Em [i, j] at the coordinates [i, j] (first coordinates) is set to a predetermined lighting amount Ec (for example, the maximum lighting amount that can be set as the lighting amount). shall be. Thereby, it is possible to suppress insufficient brightness in the divided light emitting region 62 where the coordinates (second coordinates) before moving to the coordinates [i, j] (first coordinates) do not exist within the light emitting region 61.

The calculation process of the second lighting amount Em in the second lighting amount calculating section 213 will be specifically described.

The second lighting amount calculation unit 213 first calculates the center coordinates [i, j] (first The coordinates [Xr, Yr] (second coordinates) before moving to the coordinates) are calculated.

Next, the second lighting amount calculation unit 213 calculates, for example, an area surrounded by a triangle connecting the center coordinates of the three mutually adjacent divided light emitting areas 62, which includes the coordinates [Xr, Yr] (second coordinates). The second lighting amount Em[i,j] in the divided light emitting region 62 whose central coordinate is the coordinates [i,j] (first coordinates) is calculated using the above equation (5). The coordinates (second coordinates) before moving to the center coordinates [i, j] (first coordinates) of the divided light emitting region 62 for which the second lighting amount Em [i, j] is calculated exist within the light emitting region 61 If not, the second lighting amount Em[i,j] in the divided light emitting region 62 having the coordinates [i,j] (first coordinates) as the center coordinate is set to a predetermined lighting amount Ec.

The second lighting amount calculation unit 213 calculates the second lighting amount Em in all the divided light emitting regions 62 on the light emitting region 61 by performing the above calculation process on all the divided light emitting regions 62 on the light emitting region 61. .

Following the calculation process of the second lighting amount Em in the second lighting amount calculating section 213 described above, the lighting amount setting section 214 sets each division based on the second lighting amount information BB2 output from the second lighting amount calculating section 213. A lighting amount (third lighting amount) E of the light emitting region 62 is set, and lighting amount information BB including the lighting amount (third lighting amount) E of each divided light emitting region 62 is output as a light source control signal BL.

In this embodiment, the storage unit 215 includes, for example, a frame memory that stores lighting amount information BB for one frame.

In the present embodiment, the lighting amount setting unit 214 sets the lighting amount information BB(N-1) stored in the storage unit 215 in the N-1 frame (N is a natural number) and the lighting amount information BB( N), it is determined whether the lighting amount for each divided light emitting area 62 has changed beyond a predetermined value, and predetermined processing is performed to determine the lighting amount for each divided light emitting area 62 (3rd Lighting amount information BB including lighting amount) E is generated.

Specifically, the lighting amount setting unit 214 sets the lighting amount information BB of the N frame to the lighting amount E(N-1) for each divided light emitting region 62 included in the lighting amount information BB of the N-1 frame, for example. If the lighting amount E(N) of each divided light emitting area 62 included in The intermediate value (for example, average value) of the lighting amount (third lighting amount) E(N) for each divided light emitting area 62 included in the lighting amount information BB of N frames (3 lighting amount) E(N-1) It is also possible to output the following. In this way, a sudden change in the lighting amount of each divided light emitting region 62 can be suppressed.

The lighting amount setting unit 214 also sets the lighting amount (third lighting amount) E(N-1) of each divided light emitting area 62 included in the lighting amount information BB of the N-1 frame and the lighting amount of the N frame. A mode may be adopted in which the larger one of the lighting amount (third lighting amount) E(N) for each divided light emitting region 62 included in the amount information BB is output. In this way, it is possible to avoid insufficient brightness due to detection errors in the object movement amounts Vx and Vy.

Note that in this embodiment, the processing of the lighting amount setting unit 214 is not necessarily necessary, and the second lighting amount Em of each divided light emitting area 62 included in the second lighting amount information BB2 is set to the lighting amount of each divided light emitting area 62 ( The lighting amount information BB may be generated as the third lighting amount) E.

FIG. 11 is a functional block diagram showing a configuration example of a lighting amount control section according to a comparative example. In FIG. 11, the lighting amount calculation section corresponds to the first lighting amount calculation section 211 according to the present embodiment.

As shown in FIG. 11, in the case where components corresponding to the movement amount detection section 212 and the second lighting amount calculation section 213 according to the present embodiment are not included, for example, the viewpoint of an image observer wearing an HMD is When the change in the position information of the display device 10 per unit time becomes large due to the movement of the head of the image observer, the amount of processing delay in the lighting amount control section becomes large, and the light emitting area changes with respect to the displayed image in the display area. Light emission control may be delayed, resulting in insufficient brightness in high-brightness areas.

In the display device 10 according to the present embodiment, the lighting amount control unit 21 controls the light emitting area according to the object movement amount Vx, Vy detected per predetermined unit time, as described with reference to FIGS. 6 to 10. This configuration controls the lighting amount of each divided light emitting region 62 on 61 . In the lighting amount control section 21 according to the first embodiment, by setting the predetermined unit time for detecting the object movement amounts Vx and Vy as the delay time of the processing of the lighting amount control section 21 with respect to the processing of the pixel processing section 24, A delay in light emission control of the light emitting region 61 with respect to a display image in the display region 41 can be compensated for.

As described above, the display device 10 according to the first embodiment has a light emitting region 61 divided into a plurality of divided light emitting regions 62, and is a light source unit (light source device) that illuminates the display region 41 overlapping the light emitting region 61. 60, and a signal processing unit 20 that calculates the amount of lighting for each of the plurality of divided light emitting regions 62 based on object movement amounts Vx and Vy on the light emitting region 61 according to changes in the self-position of the display device 10.

Specifically, the signal processing unit 20 includes a first lighting amount calculation unit 211 that calculates the first lighting amount Es for each of the plurality of divided light emitting regions 62 based on the input image signal, and a first lighting amount calculation unit 211 that calculates the first lighting amount Es and the object movement amount. A second lighting amount calculation unit 213 calculates a second lighting amount Em for each of the plurality of divided light emitting regions 62 based on Vx and Vy, and a second lighting amount calculation unit 213 calculates a second lighting amount Em for each of the plurality of divided light emitting regions 62 using at least the second lighting amount Em. It includes a lighting amount setting section 214 that sets the third lighting amount E, and a light source driving section 22 that drives the light source unit (light source device) 60 according to the third lighting amount E.

In the above configuration, the second lighting amount calculation unit 213 calculates the second lighting amount Em to be calculated at coordinates [i, j] (first coordinates) in the light emitting area 61 according to the object movement amounts Vx and Vy. The first lighting amount Es[Xr, Yr] at the coordinates [Xr, Yr] (second coordinates) before moving is the second lighting amount Em[i, j] at the coordinates [i, j] (first coordinates). do.

Specifically, the second lighting amount calculation unit 213 calculates the area surrounded by a triangle connecting three mutually adjacent coordinates [Xa, Ya], coordinates [Xb, Yb], and coordinates [Xc, Yc] in the light emitting region 61. When the coordinates [Xr, Yr] (second coordinates) before moving to the coordinates [i, j] (first coordinates) for which the second lighting amount Em is calculated exist in the area where the second lighting amount Em is calculated, three coordinates [ Xa, Ya], coordinates [Xb, Yb], and coordinates [Xc, Yc], and calculate the weighted average value of the first lighting amount at coordinates [i, j] (first coordinates). 2 lighting amount Em[i,j].

In addition, the second lighting amount calculation unit 213 calculates the coordinates [Xr, Yr] (first coordinates) before moving to the coordinates [i, j] (first coordinates), which is the calculation target of the second lighting amount Em, within the light emitting area 61. 2 coordinates) does not exist, a preset predetermined value (lighting amount Ec) is set as the second lighting amount Em[i, j] at the coordinates [i, j] (first coordinates).

With the above configuration, a delay in light emission control of the light emitting area 61 with respect to a display image in the display area 41 can be compensated for.

According to this embodiment, it is possible to obtain a display device 10 that can suppress delays in backlight control with respect to video signal processing.

(Embodiment 2)
FIG. 12 is a functional block diagram showing a configuration example of a lighting amount control section according to the second embodiment. Note that redundant description of components that are equivalent or the same as those of the first embodiment described above will be omitted.

In the lighting amount control section 21a according to the present embodiment, the lighting amount setting section 214a includes first lighting amount information BB1 outputted from the first lighting amount calculation section 211 and output from the second lighting amount calculation section 213. Both the second lighting amount information BB2 are input.

Furthermore, object movement amount information MD output from the movement amount detection section 212 is input to the lighting amount setting section 214a.

The lighting amount setting unit 214a sets the lighting amount (third lighting amount) E of each divided light emitting region 62 based on the magnitude |V| of the object movement vector V, and sets the lighting amount (third lighting amount) of each divided light emitting region 62. 3) The lighting amount information BB including the lighting amount E is output as the light source control signal BL. Hereinafter, the magnitude |V| of the object movement vector V will also be referred to as "object movement amount |V|". The object movement amount |V| can be expressed by the following equation (9).

|V|=√(Vx ² +Vy ² )...(9)

The object movement amount |V| may be calculated by the lighting amount setting unit 214a using the above equation (9). In this case, the object movement amount information MD output from the movement amount detection section 212 includes object movement amounts Vx and Vy.

Further, the object movement amount |V| may be calculated by the movement amount detection unit 212 using the above equation (9). In this case, the object movement amount information MD output from the movement amount detection section 212 includes the object movement amount |V|.

In this embodiment, threshold information for the object movement amount |V| is stored in advance in the storage unit 215a.

FIG. 13 is a diagram illustrating an example of a threshold value for an object movement amount. In this embodiment, as shown in FIG. 13, a first threshold Th1, a second threshold Th2, a third threshold Th3, and a fourth threshold Th4 for the object movement amount |V| are preset and stored in the storage unit 215a. has been done. In FIG. 13, the magnitude relationship between the first threshold Th1, the second threshold Th2, the third threshold Th3, and the fourth threshold Th4 is set as Th3<Th1<Th2<Th4.

For example, "0.5" is set as the first threshold Th1. Further, as the second threshold Th2, for example, "4", which is larger than the first threshold Th1 (for example, "0.5"), is set. When Th1<|V|≦Th2 (for example, 0.5<|V|≦4), the lighting amount setting unit 214a sets the coordinates [i, j] (first coordinate ), the second lighting amount Em[i,j] is applied as the lighting amount (third lighting amount) E[i,j] in each divided light emitting region 62. Note that in the following equation (10), coordinates are omitted. Further, coordinates are similarly omitted in equations (11), (12), (13), and (14), which will be described later.

E=Em...(10)

As the third threshold Th3, "0.1", which is smaller than the first threshold Th1 (for example, "0.5"), is set, for example. When |V|≦Th3 (for example, |V|≦0.1), the lighting amount setting unit 214a sets each division of coordinates [i, j] (first coordinate) as shown in equation (11) below. The first lighting amount Es[i,j] is applied as the lighting amount (third lighting amount) E[i,j] in the light emitting region 62.

E=Es...(11)

Thereby, for example, the influence of noise components included in position information acquired by an acceleration sensor can be suppressed.

As the fourth threshold Th4, for example, "5" is set, which is larger than the second threshold (for example, "4"). When Th4<|V| (for example, 5<|V|), the lighting amount setting unit 214a sets each divided light emitting region at coordinates [i, j] (first coordinates) as shown in equation (12) below. As the lighting amount (third lighting amount) E[i,j] in 62, a predetermined lighting amount Ec (for example, the maximum lighting amount that can be set as the lighting amount) is applied.

E=Ec...(12)

Thereby, for example, the influence when the position information acquired by the acceleration sensor is an abnormal value can be suppressed.

When Th3<|V|≦Th1 (for example, 0.1<|V|≦0.5), the lighting amount setting unit 214a sets coordinates [i, j] (first The lighting amount (third lighting amount) E[i,j] in each divided light emitting region 62 of the coordinates) is calculated.

E=αEm+(1-α)Es
α=(|V|-Th3)/(Th1-Th3)...(13)

As a result, when the object movement amount |V| is Th3<|V|≦Th1, the lighting amount (third lighting amount) E changes in the range Es<E≦Em according to the object movement amount |V| It becomes an intermediate value between the two, and it is possible to suppress steep fluctuations in the lighting amount (third lighting amount) E.

When Th2<|V|≦Th4 (for example, 4<|V|≦5), the lighting amount setting unit 214a sets each of the coordinates [i, j] (first coordinate) using the following equation (14). The lighting amount (third lighting amount) E[i,j] in the divided light emitting region 62 is calculated.

E=βEc+(1-β)Em
β=(|V|-Th2)/(Th4-Th2)...(14)

As a result, when the object movement amount |V| is Th2<|V|≦Th4, the lighting amount (third lighting amount) E changes in the range Em<E≦Ec according to the object movement amount |V| It becomes an intermediate value between the two, and it is possible to suppress steep fluctuations in the lighting amount (third lighting amount) E.

Note that the storage unit 215a may include a frame memory that stores lighting amount information BB for one frame, as in the first embodiment.

In this case, as in the first embodiment, the lighting amount setting unit 214a sets the lighting amount E(N-1) of each divided light emitting area 62 included in the lighting amount information BB of the N-1 frame to N. When the lighting amount E(N) of each divided light emitting region 62 included in the lighting amount information BB of the frame fluctuates beyond a predetermined value, each divided light emitting region 62 included in the lighting amount information BB of the N-1 frame changes. The intermediate value between the lighting amount (third lighting amount) E(N-1) for each light emitting area (third lighting amount) E(N-1) and the lighting amount (third lighting amount) E(N) for each divided light emitting area 62 included in the lighting amount information BB of N frames (For example, an average value) may be output. In this way, a sudden change in the lighting amount of each divided light emitting region 62 can be suppressed.

Further, as in the first embodiment, the lighting amount setting unit 214a sets the lighting amount (third lighting amount) E(N-1 ) or the lighting amount (third lighting amount) E(N) for each divided light emitting region 62 included in the lighting amount information BB of N frames, whichever is larger may be output. In this way, it is possible to avoid insufficient brightness due to detection errors in the object movement amounts Vx and Vy.

According to this embodiment, it is possible to obtain a display device 10 that can suppress delays in backlight control with respect to video signal processing.

Note that in the embodiment described above, the first lighting amount is weighted at at least three coordinates adjacent to the coordinates [Xr, Yr] (second coordinates) before moving to the coordinates [i, j] (first coordinates). An example has been described in which the average value is calculated and the weighted average value is used as the second lighting amount Em[i,j] at the coordinates [i,j] (first coordinate). A mode in which the first lighting amount at coordinates [Xr, Yr] (second coordinates) before moving to coordinates [i, j] (first coordinates) is set to the second lighting amount Em[i, j] at coordinates [i, j] (first coordinates). It may be. Specifically, the first lighting amount in the divided light emitting area where the coordinates [Xr, Yr] (second coordinates) exist before moving to the coordinates [i, j] (first coordinates) is determined by ] (first coordinates) may be the second lighting amount in the divided light emitting region having the center coordinates.

Although preferred embodiments of the present invention have been described above, the present invention is not limited to such embodiments. The contents disclosed in the embodiments are merely examples, and various changes can be made without departing from the spirit of the present invention. Appropriate changes made within the scope of the invention also fall within the technical scope of the invention.

10 Display device 11 Control device 12 Sensor 20 Signal processing section 21 Lighting amount control section 211, 211a First lighting amount calculation section 212 Movement amount detection section 213 Second lighting amount calculation section 214, 214a Lighting amount setting section 215, 215a Storage section 22 Light source drive unit 23 Brightness distribution calculation unit 24 Pixel processing unit 30 Image display panel drive unit 31 Signal output circuit 32 Scanning circuit 33 Display unit 40 Image display panel 41 Display area 42 Divided display area 48 Pixel 49R First sub-pixel 49G Second Subpixel 49B Third subpixel 60 Light source unit (light source device)
61 Light emitting area 62 Divided light emitting area 63 Light source DTL Signal line SCL Scanning line

Claims (18)

A display device whose display is controlled based on an image signal,
a light source device having a light emitting area divided into a plurality of divided light emitting areas and illuminating a display area overlapping the light emitting area;
Signal processing that detects the amount of movement of an object on the light emitting area based on position information of the display device acquired by a sensor, and calculates the amount of lighting for each of the plurality of divided light emitting areas based on the amount of movement of the object. Department and
Equipped with
The signal processing section includes:
a first lighting amount calculation unit that calculates a first lighting amount for each of the plurality of divided light emitting regions based on the image signal;
a second lighting amount calculation unit that calculates a second lighting amount for each of the plurality of divided light emitting regions based on the first lighting amount and the movement amount of the object;
Equipped with
The light source device is driven based on at least the second lighting amount,
The second lighting amount calculation unit includes:
In the light emitting region, the first lighting amount at the second coordinate before moving to the first coordinate according to the movement amount of the object is the second lighting amount at the first coordinate,
The second lighting amount calculation unit includes:
When the second coordinate exists in an area surrounded by a triangle connecting three adjacent coordinates in the light emitting area, a weighted average value of the first lighting amount at the three coordinates is calculated, and the weighted average is calculated. Let the value be the second lighting amount at the first coordinates.
Display device. A display device whose display is controlled based on an image signal,
a light source device having a light emitting area divided into a plurality of divided light emitting areas and illuminating a display area overlapping the light emitting area;
Signal processing that detects the amount of movement of an object on the light emitting area based on position information of the display device acquired by a sensor, and calculates the amount of lighting for each of the plurality of divided light emitting areas based on the amount of movement of the object. Department and
Equipped with
The signal processing section includes:
a first lighting amount calculation unit that calculates a first lighting amount for each of the plurality of divided light emitting regions based on the image signal;
a second lighting amount calculation unit that calculates a second lighting amount for each of the plurality of divided light emitting regions based on the first lighting amount and the movement amount of the object;
Equipped with
The light source device is driven based on at least the second lighting amount,
The second lighting amount calculation unit includes:
In the light emitting region, the first lighting amount at the second coordinate before moving to the first coordinate according to the movement amount of the object is the second lighting amount at the first coordinate,
The second lighting amount calculation unit includes:
Calculate a weighted average value of the first lighting amount at at least three coordinates adjacent to the second coordinate within the light emitting region, and set the weighted average value as the second lighting amount at the first coordinate.
Display device. A display device whose display is controlled based on an image signal,
a light source device having a light emitting area divided into a plurality of divided light emitting areas and illuminating a display area overlapping the light emitting area;
a signal processing unit that calculates a lighting amount for each of the plurality of divided light emitting regions based on a movement amount of an object on the light emitting region according to a change in the self-position of the display device;
Equipped with
The signal processing section includes:
a first lighting amount calculation unit that calculates a first lighting amount for each of the plurality of divided light emitting regions based on the image signal;
a second lighting amount calculation unit that calculates a second lighting amount for each of the plurality of divided light emitting regions based on the first lighting amount and the movement amount of the object;
Equipped with
The light source device is driven based on at least the second lighting amount,
The second lighting amount calculation unit includes:
In the light emitting region, the first lighting amount at the second coordinate before moving to the first coordinate according to the movement amount of the object is the second lighting amount at the first coordinate,
The second lighting amount calculation unit includes:
When the second coordinate exists in an area surrounded by a triangle connecting three adjacent coordinates in the light emitting area, a weighted average value of the first lighting amount at the three coordinates is calculated, and the weighted average is calculated. A display device in which a value is the second lighting amount at the first coordinate. A display device whose display is controlled based on an image signal,
a light source device having a light emitting area divided into a plurality of divided light emitting areas and illuminating a display area overlapping the light emitting area;
a signal processing unit that calculates a lighting amount for each of the plurality of divided light emitting regions based on a movement amount of an object on the light emitting region according to a change in the self-position of the display device;
Equipped with
The signal processing section includes:
a first lighting amount calculation unit that calculates a first lighting amount for each of the plurality of divided light emitting regions based on the image signal;
a second lighting amount calculation unit that calculates a second lighting amount for each of the plurality of divided light emitting regions based on the first lighting amount and the movement amount of the object;
Equipped with
The light source device is driven based on at least the second lighting amount,
The second lighting amount calculation unit includes:
In the light emitting region, the first lighting amount at the second coordinate before moving to the first coordinate according to the movement amount of the object is the second lighting amount at the first coordinate,
The second lighting amount calculation unit includes:
A weighted average value of the first lighting amount at at least three coordinates adjacent to the second coordinate in the light emitting region is calculated, and the weighted average value is set as the second lighting amount at the first coordinate. . The second lighting amount calculation unit includes:
The display device according to any one of claims 1 to 4 , wherein when the second coordinate does not exist within the light emitting region, a preset predetermined value is set as the second lighting amount at the first coordinate. A display device whose display is controlled based on an image signal,
a light source device having a light emitting area divided into a plurality of divided light emitting areas and illuminating a display area overlapping the light emitting area;
a signal processing unit that calculates a lighting amount for each of the plurality of divided light emitting regions based on a movement amount of an object on the light emitting region according to a change in the self-position of the display device;
Equipped with
The signal processing section includes:
a first lighting amount calculation unit that calculates a first lighting amount for each of the plurality of divided light emitting regions based on the image signal;
a second lighting amount calculation unit that calculates a second lighting amount for each of the plurality of divided light emitting regions based on the first lighting amount and the movement amount of the object;
Equipped with
The light source device is driven based on at least the second lighting amount,
The second lighting amount calculation unit includes:
In the light emitting region, the first lighting amount at the second coordinate before moving to the first coordinate according to the movement amount of the object is the second lighting amount at the first coordinate,
The second lighting amount calculation unit includes:
When the second coordinate does not exist within the light emitting area, a predetermined value set in advance is set as the second lighting amount at the first coordinate. a lighting amount setting unit that sets a third lighting amount for each of the plurality of divided light emitting regions based on at least the second lighting amount;
a light source drive unit that drives the light source device according to the third lighting amount;
The display device according to any one of claims 1 to 6 , further comprising: The lighting amount setting section includes:
According to claim 7 , the second lighting amount is set as the third lighting amount when the amount of movement of the object is larger than a first threshold and less than or equal to a second threshold that is larger than the first threshold. Display device as described. The lighting amount setting section includes:
The display device according to claim 8 , wherein the first lighting amount is set as the third lighting amount when the amount of movement of the object is equal to or less than a third threshold value that is smaller than the first threshold value. A display device whose display is controlled based on an image signal,
a light source device having a light emitting area divided into a plurality of divided light emitting areas and illuminating a display area overlapping the light emitting area;
a signal processing unit that calculates a lighting amount for each of the plurality of divided light emitting regions based on a movement amount of an object on the light emitting region according to a change in the self-position of the display device;
Equipped with
The signal processing section includes:
a first lighting amount calculation unit that calculates a first lighting amount for each of the plurality of divided light emitting regions based on the image signal;
a second lighting amount calculation unit that calculates a second lighting amount for each of the plurality of divided light emitting regions based on the first lighting amount and the movement amount of the object;
Equipped with
The light source device is driven based on at least the second lighting amount,
a lighting amount setting unit that sets a third lighting amount for each of the plurality of divided light emitting regions based on at least the second lighting amount;
a light source drive unit that drives the light source device according to the third lighting amount;
Furthermore,
The lighting amount setting section includes:
If the amount of movement of the object is greater than a first threshold and less than or equal to a second threshold greater than the first threshold, setting the second lighting amount as the third lighting amount;
The lighting amount setting section includes:
A display device that sets the first lighting amount as the third lighting amount when the amount of movement of the object is equal to or less than a third threshold value that is smaller than the first threshold value. The lighting amount setting section includes:
According to any one of claims 8 to 10 , a predetermined value set in advance is set as the third lighting amount when the amount of movement of the object is larger than a fourth threshold value that is larger than the second threshold value. display device. A display device whose display is controlled based on an image signal,
a light source device having a light emitting area divided into a plurality of divided light emitting areas and illuminating a display area overlapping the light emitting area;
a signal processing unit that calculates a lighting amount for each of the plurality of divided light emitting regions based on a movement amount of an object on the light emitting region according to a change in the self-position of the display device;
Equipped with
The signal processing section includes:
a first lighting amount calculation unit that calculates a first lighting amount for each of the plurality of divided light emitting regions based on the image signal;
a second lighting amount calculation unit that calculates a second lighting amount for each of the plurality of divided light emitting regions based on the first lighting amount and the movement amount of the object;
Equipped with
The light source device is driven based on at least the second lighting amount,
a lighting amount setting unit that sets a third lighting amount for each of the plurality of divided light emitting regions based on at least the second lighting amount;
a light source drive unit that drives the light source device according to the third lighting amount;
Furthermore,
The lighting amount setting section includes:
If the amount of movement of the object is greater than a first threshold and less than or equal to a second threshold greater than the first threshold, setting the second lighting amount as the third lighting amount;
The lighting amount setting section includes:
A display device in which a predetermined value set in advance is set as the third lighting amount when the amount of movement of the object is larger than a fourth threshold value that is larger than the second threshold value. The lighting amount setting section includes:
When the amount of movement of the object is greater than a third threshold smaller than the first threshold and less than or equal to the first threshold, the intermediate value between the first lighting amount and the second lighting amount is set to The display device according to any one of claims 8 to 12 , wherein the third lighting amount is set. A display device whose display is controlled based on an image signal,
a light source device having a light emitting area divided into a plurality of divided light emitting areas and illuminating a display area overlapping the light emitting area;
a signal processing unit that calculates a lighting amount for each of the plurality of divided light emitting regions based on a movement amount of an object on the light emitting region according to a change in the self-position of the display device;
Equipped with
The signal processing section includes:
a first lighting amount calculation unit that calculates a first lighting amount for each of the plurality of divided light emitting regions based on the image signal;
a second lighting amount calculation unit that calculates a second lighting amount for each of the plurality of divided light emitting regions based on the first lighting amount and the movement amount of the object;
Equipped with
The light source device is driven based on at least the second lighting amount,
a lighting amount setting unit that sets a third lighting amount for each of the plurality of divided light emitting regions based on at least the second lighting amount;
a light source drive unit that drives the light source device according to the third lighting amount;
Furthermore,
The lighting amount setting section includes:
If the amount of movement of the object is greater than a first threshold and less than or equal to a second threshold greater than the first threshold, setting the second lighting amount as the third lighting amount;
The lighting amount setting section includes:
When the amount of movement of the object is greater than a third threshold smaller than the first threshold and less than or equal to the first threshold, the intermediate value between the first lighting amount and the second lighting amount is set to Display device set as the third lighting amount. The lighting amount setting section includes:
When the amount of movement of the object is greater than the second threshold and less than or equal to a fourth threshold greater than the second threshold, an intermediate value between the second lighting amount and a preset predetermined value is set. The display device according to any one of claims 8 to 14 , wherein the third lighting amount is set. A display device whose display is controlled based on an image signal,
a light source device having a light emitting area divided into a plurality of divided light emitting areas and illuminating a display area overlapping the light emitting area;
a signal processing unit that calculates a lighting amount for each of the plurality of divided light emitting regions based on a movement amount of an object on the light emitting region according to a change in the self-position of the display device;
Equipped with
The signal processing section includes:
a first lighting amount calculation unit that calculates a first lighting amount for each of the plurality of divided light emitting regions based on the image signal;
a second lighting amount calculation unit that calculates a second lighting amount for each of the plurality of divided light emitting regions based on the first lighting amount and the movement amount of the object;
Equipped with
The light source device is driven based on at least the second lighting amount,
a lighting amount setting unit that sets a third lighting amount for each of the plurality of divided light emitting regions based on at least the second lighting amount;
a light source drive unit that drives the light source device according to the third lighting amount;
Furthermore,
The lighting amount setting section includes:
If the amount of movement of the object is greater than a first threshold and less than or equal to a second threshold greater than the first threshold, setting the second lighting amount as the third lighting amount;
The lighting amount setting section includes:
When the amount of movement of the object is greater than the second threshold and less than or equal to a fourth threshold greater than the second threshold, an intermediate value between the second lighting amount and a preset predetermined value is set. A display device that is set as the third lighting amount. The lighting amount setting section includes:
The third lighting amount of the N-1 frame (N is a natural number) is compared with the third lighting amount of the N frame, and the larger one is outputted to the light source driving section . Display device as described. A display device whose display is controlled based on an image signal,
a light source device having a light emitting area divided into a plurality of divided light emitting areas and illuminating a display area overlapping the light emitting area;
a signal processing unit that calculates a lighting amount for each of the plurality of divided light emitting regions based on a movement amount of an object on the light emitting region according to a change in the self-position of the display device;
Equipped with
The signal processing section includes:
a first lighting amount calculation unit that calculates a first lighting amount for each of the plurality of divided light emitting regions based on the image signal;
a second lighting amount calculation unit that calculates a second lighting amount for each of the plurality of divided light emitting regions based on the first lighting amount and the movement amount of the object;
Equipped with
The light source device is driven based on at least the second lighting amount,
a lighting amount setting unit that sets a third lighting amount for each of the plurality of divided light emitting regions based on at least the second lighting amount;
a light source drive unit that drives the light source device according to the third lighting amount;
Furthermore,
The lighting amount setting section includes:
A display device that compares a third lighting amount of an N-1 frame (N is a natural number) with a third lighting amount of an N frame, and outputs the larger one to the light source driving section.

Images