JP2016014738A - Display device and display method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress reduction in an image quality.SOLUTION: A display device is provided that comprises: a control unit that creates from an input image signal an output image signal having luminance of a pixel converted by use of a conversion coefficient having a first threshold set, determines whether an image based on the input image signal is a specific image, and changes the first threshold to a second threshold different from the first threshold when the image is the specific image; and an image display panel unit that displays the image on the basis of the output image signal. In such the display device, even on a high gradation value side of the input image signal including an image of a primary color system, luminance of the image to be displayed is not kept constant in accordance with a change in gradation value, and is configured to vary therein, which in turn reduction in an image quality of the display image is prevented.

Description

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

  A display device has been proposed in which the brightness of the backlight is controlled in accordance with the input image signal to reduce power consumption and display quality when displaying moving images and still images is improved (for example, Patent Document 1). ).

JP 2011-248352 A

  The present invention provides a display device and a display method in which deterioration in image quality is suppressed.

  According to one aspect of the present invention, an output image signal obtained by converting the luminance of a pixel using a conversion coefficient having a first threshold value is generated from an input image signal, and the image based on the input image signal is a specific image. A control unit that changes the first threshold value to a second threshold value that is different from the first threshold value, and an image display panel unit that displays an image based on the output image signal. , A display device.

It is a figure which shows the structural example of the display apparatus in 1st Embodiment. It is a figure which shows an example of the display method of the display apparatus in 1st Embodiment. It is a figure which shows the hardware structural example of the display apparatus in 2nd Embodiment. It is a figure which shows the structural example of the image display panel contained in the display apparatus in 2nd Embodiment. It is a figure which shows the structural example of the light source device contained in the display apparatus in 2nd Embodiment. It is a figure which shows the function structural example contained in the display apparatus in 2nd Embodiment. It is a figure which shows the function structural example of the signal processing part contained in the display apparatus in 2nd Embodiment. It is a conceptual diagram of reproduction HSV color space reproducible with the display apparatus in 2nd Embodiment. It is a flowchart of the signal processing performed by the signal processing part contained in the display apparatus in 2nd Embodiment. It is a flowchart of the image analysis process performed by the signal processing part contained in the display apparatus in 2nd Embodiment. It is a figure for demonstrating the setting value according to the pixel count based on the expansion coefficient of the image analysis process performed by the signal processing part contained in the display apparatus in 3rd Embodiment. It is a figure for demonstrating the determination method of the minimum value performed with the signal processing part contained in the display apparatus in 4th Embodiment. It is a figure for demonstrating the display by the division | segmentation drive control of the display apparatus in 5th Embodiment. It is a flowchart of the image analysis process performed by the signal processing part contained in the display apparatus in 5th Embodiment.

Embodiments will be described below with reference to the drawings.
It should be noted that the disclosure is merely an example, and those skilled in the art can easily conceive of appropriate changes while maintaining the gist of the invention are naturally included in the scope of the present invention. In addition, the drawings may be schematically represented with respect to the width, thickness, shape, and the like of each part in comparison with actual aspects for the sake of clarity of explanation, but are merely examples, and the interpretation of the present invention is not limited. It is not limited.

  In the present invention and each drawing, the same reference numerals are given to the same elements as those described above with reference to the previous drawings, and the detailed description may be omitted as appropriate.

[First Embodiment]
The display device of the first embodiment will be described with reference to FIG.

  FIG. 1 is a diagram illustrating a configuration example of a display device according to the first embodiment. 1A shows a configuration example of the display device 1, and FIG. 1B shows a graph showing a change in luminance of an output image with respect to a gradation value of an input image signal. In FIG. 1B, the horizontal axis represents the gradation value, and the vertical axis represents the normalized output luminance with respect to the gradation value.

  As shown in FIG. 1A, the display device 1 includes a control unit 2, an image display panel unit 3 that displays an image based on an output image signal output from the control unit 2, and an image display panel unit 3. And an illumination unit 4 that illuminates from the back (backlight) or the front (front light).

  The control unit 2 generates an output image signal in which the luminance of the pixel is changed from the input image signal using the conversion coefficient in which the first threshold is set, and whether or not the image based on the input image signal is a specific image If the image is a specific image, the first threshold is changed to a second threshold different from the first threshold. The specific image includes, for example, a pixel whose conversion coefficient calculated from the input image signal is a conversion coefficient outside the first threshold. Moreover, the control part 2 adjusts the brightness | luminance of the illumination part 4 based on the conversion coefficient at the time of producing | generating an output image signal. For example, when the luminance of the pixel of the image display panel unit 3 is improved by expanding the input image signal by the conversion coefficient, the luminance of the illumination unit 4 is increased by the amount of the improvement of the luminance of the pixel of the image display panel unit 3. By reducing, power consumption is reduced.

  One aspect of such a conversion coefficient is an expansion coefficient α. The image display panel unit 3 includes, for example, pixels having sub-pixels that display red (R), green (G), and blue (B) and sub-pixels that display white (W). Is driven by PWM (Pulse Width Modulation) control. In this case, when the control unit 2 improves the luminance of the entire image of the image display panel unit 3 based on the input image signal by the expansion coefficient α, the illumination unit 4 converts the PWM value to 1 / α which is the inverse of the expansion coefficient α. By lowering the illumination brightness based on this, it is possible to display with the same brightness as the image based on the input image signal. Details of the conversion coefficient (expansion coefficient α) and the image display panel unit 3 will be described in the second embodiment.

  The image is analyzed for each frame, and the expansion coefficient (α value) of the input image signal applied to the image is defined in the following range.

α _min ≦ α ≦ α _max (A)

However, α _min is the minimum value of α value, and α _max is the maximum value of α value.

  By the way, in the display apparatus 1, in order to reduce the power consumption of the illumination unit 4, it is desired to reduce the maximum value of the PWM value.

In Expression (A), when α _min of the expansion coefficient α is increased, the maximum value (1 / α _min ) of 1 / α that is a conversion coefficient for the illumination unit 4 is decreased. Thus, the luminance is reduced by improving the luminance of the image based on the input image signal using the expansion coefficient α whose range is limited and reducing the maximum value of the PWM value of the illumination unit 4 using 1 / α. (Adjustment) and low power consumption can be achieved. At this time, for example, when displaying a primary color system such as red, as shown in FIG. 1B, the high gradation value (230 to 255) of the input image signal corresponds to a change in the gradation value. The luminance of the pixels of the image display panel unit 3 does not change and becomes substantially constant (brightness collapse), and the image quality of the display image is deteriorated. FIG. 1B shows the case where the gamma value is 2.2.

Therefore, an example of a display method executed by the display device 1 including the above configuration will be described with reference to FIG. 2 together with FIG.
FIG. 2 is a diagram illustrating an example of a display method of the display device according to the first embodiment. 2A, 2 </ b> C, and 2 </ b> D are diagrams illustrating display examples of images displayed by the image display panel unit 3 using VGA (vertical 480 lines, horizontal 640 lines) as an example. FIG. 2B is a graph showing lightness with respect to saturation. However, in FIG. 2B, the hue is not taken into consideration and is represented in two dimensions.

The ratio of the maximum luminance between the W subpixel of the image display panel unit 3 and each of the RGB subpixels is as follows.
χ = luminance of W subpixel / luminance of RGB subpixel = 1

In the display device 1, in the formula (A), the α value that is the expansion coefficient is defined as α1 larger than α _min as follows.

α _min (second threshold value) <α1 (first threshold value) ≦ α ≦ α _max (B)

Here, the image display panel unit 3 included in the display device 1 is based on the input image signal, for example, as shown in FIG. A display method for displaying an image including the red region B having a value of 255 will be described. In the formulas (A) and (B), for example, it is assumed that 1 is set for α _min , 1.2 is set for α 1, and 2 is set for α _max .

In such a display device 1, when an input image signal is input, the control unit 2 calculates an α value for each pixel from the input image signal. At this time, the control unit 2 determines whether or not the image based on the input image signal is a specific image. The specific image is determined based on whether or not the number N of pixels in the region B composed of pixels having an α value lower than α1 exceeds a threshold pixel number N _count1 (for example, 1200), which is an example of an evaluation value.
As an example of the determination, a case will be described in which an image based on an input image signal includes a region B in which the number N of pixels of 30 vertical lines × 30 horizontal lines is 900, as shown in FIG.

  When this image is plotted in the extended HSV color space (H is Hue, S is Saturation, and V is Lightness (Value)), as shown in FIG. A red color of 255 is the maximum (lightness 1) in the extended HSV color space. That is, since the brightness of the area B cannot be expanded any more, the α value of the pixels in the area B is 1. Similarly, as shown in FIG. 2B, the α value of the pixel in the white region A having a gradation value of 255 is 2.

In the image based on the input image signal, the region B composed of one pixel having an α value less than α1 (1.2) has 900 pixels, and the threshold pixel number N _count1 (1200) Therefore, it is determined that the image is not a specific image. Therefore, when the input image signal is input, the control unit 2 generates an output image signal based on an α value within a range of α1 (1.2) and _αmax (2). In this case, the maximum value of the PWM value of the illumination unit 4 is 255 / 1.2 = 213, so that power consumption can be reduced.

  Next, a case will be described in which an image based on an input image signal includes a region B having a length of 100 lines × width of 100 lines and a pixel number N of 10,000 as shown in FIG.

In this case, the number N of pixels in the region B composed of pixels having an α value of 10000 is 10000, which exceeds the threshold pixel number N _count1 (1200). For this reason, the control unit 2 determines that the image based on the input image signal is a specific image, and applies α _min (1). Therefore, the control unit 2 generates an output image signal based on the α value within the range of α _min (1) and α _max (2) from the α value calculated for each pixel from the input image signal. At this time, the maximum PWM value of the illumination unit 4 is 255/1 = 255.

Further, as shown in FIG. 2D, when the image based on the input image signal includes only a region B having a length of 480 lines and a width of 640 lines and a pixel number N of 307200, the threshold value is similar to the above. The number of pixels exceeds N _count1 (1200) and is determined to be a specific image. Therefore, the control unit 2 generates an output image signal based on the α value within the range of α _min (1) and α _max (2) from the α value calculated for each pixel from the input image signal. At this time, the maximum PWM value of the illumination unit 4 is 255/1 = 255.

  In the display device 1, the control unit 2 generates an output image signal obtained by converting the luminance of the pixel using the conversion coefficient that is calculated from the input image signal and set with the first threshold value. The control unit 2 determines whether or not the image based on the input image signal is a specific image composed of pixels having a transform coefficient outside the first threshold, and if the image is the specific image, the first threshold Is changed to a second threshold different from the first threshold.

  For this reason, even on the high gradation value side of the input image signal including the primary color image, the brightness of the displayed image does not become constant according to the change of the gradation value, and the image quality of the display image is changed. Reduction is prevented. Further, in the first embodiment, since the first threshold value (α1) is not changed when the image is not a specific image based on the number of pixels of the transform coefficient outside the first threshold value (α1), low power consumption is achieved. Can be achieved.

In the first embodiment, the case where the expansion coefficient α is switched between the first threshold value (α1) and the second threshold value (α _min ) has been described as an example. However, the threshold value is not limited to two, and α, α2, α3,..., Αn (α1 <α2 <α3 <... <αn) may be prepared and switched according to a plurality of stages. . Similarly, n _{count values} , N _count1 , N _count3 ,..., N _countn can be prepared for the evaluation value (threshold pixel number N _count1 ). At this time, when the number of pixels of α value _{satisfying αn} −1 <α value < _αn is larger than the threshold pixel number N _{countn, αn} −1 is applied as the threshold value of α value, and the threshold pixel number N _countn is exceeded. If it is smaller, αn may be applied as the threshold value of the α value.

Whether or not the image is a specific image is determined by calculating the conversion coefficient of each pixel included in the input image signal of one image in the first embodiment, and calculating the conversion coefficient of the pixel outside the first threshold value. Although the determination is made according to the number of pixels, the determination method is not limited to this. For example, you may determine whether it is a specific image based on the information contained in an input image signal, for example, the gradation value of each pixel. That is, in the image based on the input image signal, when the number of pixels equal to or higher than the predetermined gradation value exceeds the threshold pixel number, the first threshold value can be changed to the second threshold value.
Furthermore, the determination may be made according to the number of pixels of conversion coefficients outside the first threshold included in the input image signals of a plurality of images. For example, you may determine whether it is a specific image according to the average value, the total value, etc. of the pixel number of the conversion coefficient outside a 1st threshold value contained in the input image signal of a several continuous image. Further, the coordinate information of the pixel having the conversion coefficient outside the first threshold may be acquired, and it may be determined whether or not the image is the specific image based on the coordinate information of the pixel having the conversion coefficient outside the first threshold. For example, you may determine whether it is a specific image based on the density of the pixel which has a conversion coefficient outside a 1st threshold value, the distance between the pixels which have a conversion coefficient outside a 1st threshold value, etc.

[Second Embodiment]
In the second embodiment, the display device of the first embodiment will be described more specifically.
First, a hardware configuration example of the display device according to the second embodiment will be described with reference to FIG.

FIG. 3 is a diagram illustrating a hardware configuration example of the display device according to the second embodiment.
The display device 100 is an embodiment of the display device 1 shown in FIG. 1, and the entire device is controlled by a control unit 100a.

  In the control unit 100a, a CPU (Central Processing Unit) 100a1, a RAM (Random Access Memory) 100a2, a ROM (Read Only Memory) 100a3, and a plurality of peripheral devices can mutually input and output signals via a bus 100f. It is connected to the.

  The CPU 100a1 controls the entire display device 100 based on an OS (Operating System) program or application program stored in the ROM 100a3 and various data expanded in the RAM 100a2. At the time of execution of the process, it may be operated by an OS program or an application program temporarily stored in the RAM 100a2.

  The RAM 100a2 is used as a main storage device of the control unit 100a. The RAM 100a2 temporarily stores at least part of OS programs and application programs to be executed by the CPU 100a1. The RAM 100a2 stores various data necessary for processing by the CPU 100a1.

  The ROM 100a3 is a read-only semiconductor storage device that stores an OS program, an application program, and fixed data that is not rewritten. Further, instead of the ROM 100a3 or in addition to the ROM 100a3, a semiconductor storage device such as a flash memory can be used as a secondary storage device.

  Peripheral devices connected to the bus 100f include a display driver IC (Integrated Circuit) 100b, a light source control driver IC 100c, an input / output interface 100d, and a communication interface 100e.

  An image display panel 200 is connected to the display driver IC 100b. The display driver IC 100 b displays an image on the image display panel 200 by outputting an output signal to the image display panel 200. The display driver IC 100b can also realize at least a part of functions of an image display panel driving unit described later.

  A light source device 300 is connected to the light source control driver IC 100c. The light source control driver IC 100 c drives the light source according to the light source control signal and controls the luminance of the light source device 300. The light source control driver IC 100c realizes at least a part of functions of a light source device driving unit described later.

  An input device for inputting user instructions is connected to the input / output interface 100d. For example, an input device such as a keyboard, a mouse used as a pointing device, or a touch panel is connected. The input / output interface 100d transmits a signal sent from the input device to the CPU 100a1.

  The communication interface 100e is connected to the network 1000. The communication interface 100e transmits / receives data to / from other computers or communication devices via the network 1000.

  With the hardware configuration as described above, the processing functions of the present embodiment can be realized.

  Next, a configuration example of the image display panel 200 will be described with reference to FIG.

  FIG. 4 is a diagram illustrating a configuration example of an image display panel included in the display device according to the second embodiment.

  In the image display panel 200, the pixels 201 arranged in a two-dimensional matrix have a first subpixel 202R, a second subpixel 202G, a third subpixel 202B, and a fourth subpixel 202W. The first subpixel 202R displays red, the second subpixel 202G displays green, the third subpixel 202B displays blue, and the fourth subpixel 202W displays white. The colors of the first sub-pixel 202R, the second sub-pixel 202G, and the third sub-pixel 202B are not limited to this, and it is sufficient that the colors such as complementary colors are different. Further, the color of the fourth sub-pixel 202W is not limited to white, but may be yellow, for example, but white is effective in reducing power. Further, the arrangement of the first to fourth sub-pixels 202R, 202G, 202B, and 202W is not limited to this, and thinning processing may be performed as appropriate. The fourth subpixel 202W is preferably brighter than the first subpixel 202R, the second subpixel 202G, and the third subpixel 202B when irradiated with the same light source lighting amount. Hereinafter, when it is not necessary to distinguish the first sub-pixel 202R, the second sub-pixel 202G, the third sub-pixel 202B, and the fourth sub-pixel 202W, they are referred to as sub-pixels 202.

  More specifically, the image display panel 200 is a transmissive color liquid crystal display panel, and each of the first sub-pixel 202R, the second sub-pixel 202G, the third sub-pixel 202B, and the image observer is respectively Color filters that pass red, green, and blue are arranged. Further, no color filter is disposed between the fourth sub-pixel 202W and the image observer. The fourth subpixel 202W may be provided with a transparent resin layer instead of the color filter. By providing the transparent resin layer in this way, it is possible to suppress the occurrence of a large step in the fourth subpixel 202W by not providing the color filter in the fourth subpixel 202W.

  The signal output circuit 410 and the scanning circuit 420 included in the image display panel driving unit 400 respectively include the first to fourth subpixels 202R, 202G, 202B, and 202W of the image display panel 200 through the signal line DTL and the scanning line SCL. And are electrically connected. The sub-pixel 202 is connected to the signal line DTL and is connected to the scanning line SCL via a switching element (for example, a thin film transistor TFT). The image display panel driving unit 400 controls the operation (light transmittance) of the sub-pixel 202 by selecting the sub-pixel 202 by the scanning circuit 420 and sequentially outputting video signals from the signal output circuit 410.

  Next, a configuration example of the light source device 300 will be described with reference to FIG.

  FIG. 5 is a diagram illustrating a configuration example of a light source device included in the display device according to the second embodiment.

  The light source device 300 includes a light guide plate 301 and a sidelight light source 302 in which a plurality of light sources 303 are arranged at a position facing the entrance surface E with at least one side surface of the light guide plate 301 as an entrance surface E. As an example of the plurality of light sources 303, a light emitting diode (LED) having the same color (for example, white) can be used. In this case, a current or a PWM value (duty ratio or the like) is independently applied. Can be controlled. The light sources 303 are arranged along one side surface of the light guide plate 301. When the direction in which the light sources 303 are arranged is a light source arrangement direction LY, the light source 303 is guided from the incident surface E toward the incident direction LX orthogonal to the light source arrangement direction LY. Incident light from the light source 303 enters the light plate 301. For example, the light source device 300 is not limited to a planar light source device using such a light-emitting diode as a sidelight light source, but may use a direct light source device in which a light source is disposed at a position facing the image display panel 200. Is possible.

  The light source device driving unit 500 controls the light amount of the light source 303 by adjusting a current supplied to the light source 303 and a PWM value based on a light source control signal to be described later, and controls the luminance (light intensity) of the light source device 300. Control.

  Next, a functional configuration example included in the display device 100 including such a configuration will be described with reference to FIG.

  FIG. 6 is a diagram illustrating a functional configuration example included in the display device according to the second embodiment.

  The display device 100 includes an image input unit 110, a signal processing unit 120, an image display panel 200, a light source device 300, an image display panel driving unit 400, and a light source device driving unit 500.

The image input unit 110 inputs the input signal SRGB to the signal processing unit 120. The input signal SRGB, the input signal value for the first primary color x1 _{(p, q),} the input signal values for the second primary x2 _{(p, q),} includes an input signal value for the third primary x3 _{(p, q)} is . In the second embodiment, the first primary color is red, the second primary color is green, and the third primary color is blue.

The signal processing unit 120 is connected to an image display panel driving unit 400 that drives the image display panel 200 and a light source device driving unit 500 that drives the light source device 300. The signal processing unit 120 outputs an output signal value X1 _{(p, q)} of the first subpixel, an output signal value X2 _{(p, q) of} the second subpixel, and an output signal value X3 _{(p, q) of} the third subpixel. In addition, the output signal SRGBW including the output signal value X4 _{(p, q) of} the fourth subpixel that displays the fourth color is input to the image display panel driving unit 400 to control image display. In the second embodiment, it is assumed that the fourth color is white. The signal processing unit 120 is an embodiment of the control unit 2 of the first embodiment.

In the image display panel 200, P × Q pixels 201 are arranged in a two-dimensional matrix.
The image display panel driving unit 400 includes a signal output circuit 410 and a scanning circuit 420, and drives the image display panel 200. The image display panel 200 and the image display panel drive unit 400 are an embodiment of the image display panel unit 3.

  The light source device 300 is disposed on the back surface of the image display panel 200 and illuminates the image display panel 200 by irradiating light toward the image display panel 200.

  The light source device driving unit 500 controls the luminance of the light source device 300 based on the light source control signal SBL output from the signal processing unit 120. The light source device 300 and the light source device driving unit 500 are an embodiment of the illumination unit 4.

  The processing operation of the signal processing unit 120 is realized by the display driver IC 100b or the CPU 100a1 illustrated in FIG.

  When the display driver IC 100b is used, the input signal SRGB is input to the display driver IC 100b via the CPU 100a1. The display driver IC 100b generates an output signal SRGBW and controls the image display panel 200. Further, the light source control signal SBL is generated and output to the light source control driver IC 100c via the bus 100f.

  When realized by the CPU 100a1, the output signal SRGBW is input from the CPU 100a1 to the display driver IC 100b. The light source control signal SBL is also generated by the CPU 100a1 and output to the light source control driver IC 100c through the bus 100f.

  Next, a functional configuration example further provided in the signal processing unit 120 of the display device 100 will be described with reference to FIG.

FIG. 7 is a diagram illustrating a functional configuration example of the signal processing unit included in the display device according to the second embodiment.
7A shows an example of the functional configuration of the signal processing unit, and FIG. 7B shows an example of the functional configuration of the image analysis unit included in the signal processing unit. FIG. 7C shows a reference value, a threshold pixel number for the number of pixels of the expansion coefficient α smaller than the reference value, and a minimum value (an example of a set value) set when the number is smaller than the threshold pixel number. Yes.

  As illustrated in FIG. 7A, the signal processing unit 120 includes an image analysis unit 121, an image processing unit 122, and a light source control unit 123. An input signal SRGB is input from the image input unit 110 to the signal processing unit 120. The input signal SRGB includes color information of an image displayed at each location for each pixel 201 of the image display panel 200.

  The image analysis unit 121 calculates a conversion coefficient for converting the luminance of the pixel 201 for each pixel 201 in accordance with the input signal SRGB, and determines the conversion coefficient based on a predetermined range from the calculated conversion coefficient. The pixel 201 can adjust (convert) the luminance of the pixel 201 by including the fourth sub-pixel 202W. Details of the image analysis unit 121 will be described later.

  The image processing unit 122 generates the output signal SRGBW based on the input signal SRGB and the conversion coefficient of the pixel 201 determined by the image analysis unit 121, and outputs the output signal SRGBW to the image display panel driving unit at a predetermined timing. Output to 400.

  The light source control unit 123 calculates the luminance information of the light source device 300 based on the conversion coefficient determined by the image analysis unit 121, and determines the lighting amount of the sidelight light source 302. The light source control unit 123 outputs a light source control signal SBL corresponding to the lighting amount to the light source device driving unit 500.

  As shown in FIG. 7B, the image analysis unit 121 included in the signal processing unit 120 further includes a threshold holding unit 121a, a conversion coefficient determination unit 121b, an image comparison unit 121c, and a threshold setting unit 121d. Including.

The threshold holding unit 121a holds threshold information that defines a range of conversion coefficients. The threshold value holding unit 121a is a threshold pixel number (the number of pixels used for comparison with the reference value serving as a reference of the pixel to be counted and the pixel number N of the pixel to be counted in the image comparison unit 121c described later. An example of an evaluation value), a threshold value setting unit 121d described later holds a setting value (an example of a first threshold value) that is a value that is set as the minimum value of the conversion coefficient in accordance with the comparison result of the image comparison unit 121c. . More specifically, α1 satisfying the formula (B) of the first embodiment with respect to α _max and α _min as reference values for the expansion coefficient α that is one aspect of the transform coefficient (for example, 1.2), Na (for example, 1200) as the threshold pixel number and α1 as the set value are held.

The conversion coefficient determination unit 121b calculates a conversion coefficient for converting the luminance of the pixel 201 for each pixel 201 in accordance with the input signal SRGB. The conversion coefficient determination unit 121b determines a conversion coefficient from the calculated conversion coefficient according to the setting of a threshold setting unit 121d described later. For example, the transform coefficient determination unit 121b determines the α value based on the α value calculated for each pixel 201 based on the setting of the threshold value setting unit 121d and the range of α _min or α1 to α _max .

  As shown in FIG. 7C, the image comparison unit 121c includes the conversion coefficients calculated by the conversion coefficient determination unit 121b based on the reference value and the threshold pixel number held in the threshold holding unit 121a. The number N of pixels having a conversion coefficient (α value) smaller than the reference value (α1) of the range held by the threshold holding unit 121a is counted, and the counted number N of pixels is compared with the threshold pixel number Na (1200). .

The threshold setting unit 121d sets the minimum value of the range of transform coefficients used for determining the transform coefficient based on the setting value held in the threshold holding unit 121a according to the comparison result of the image comparison unit 121c. In the second embodiment, when the pixel number N is less than the threshold pixel number Na, α1 which is a set value is applied to the minimum value as a range used for determining the α value. When the pixel number N is equal to or greater than the threshold pixel number Na, α _min is applied to the minimum value.

  In the present invention, the image comparison unit 121c counts the number N of pixels having a conversion coefficient smaller than the reference value held in the threshold value holding unit 121a. However, the present invention is not limited to this, and the image comparison unit 121c has a conversion coefficient larger than the reference value. The number of pixels N2 may be counted and compared with the threshold number of pixels. In addition, the threshold setting unit 121d applies the setting value to the minimum value of the α value when the counted pixel number N is less than the threshold pixel number Na. However, the present invention is not limited to this, and the pixel number N is the threshold pixel number Na. In the above case, the set value may be set to the minimum value of the α value.

  Next, the case where the expansion coefficient α is used as a conversion coefficient as one aspect of the conversion coefficient for improving the luminance of the pixel or the conversion coefficient for reducing the luminance of the light source device 300 will be described with reference to FIG.

  FIG. 8 is a conceptual diagram of a reproduction HSV color space that can be reproduced by the display device according to the second embodiment.

  In the display device 100, by providing the pixel 201 with the fourth sub-pixel 202 </ b> W that outputs the fourth color (white), the dynamic range of brightness in the reproduction HSV color space that can be reproduced by the display device 100 can be expanded.

  As shown in FIG. 8, the reproduction HSV color space to which the fourth color is added is a cylindrical shape that can be displayed by the first subpixel 202R, the second subpixel 202G, and the third subpixel 202B. The HSV color space has a shape in which a solid body having a substantially trapezoidal shape in which the maximum value of the lightness V decreases as the saturation S increases. The signal processing unit 120 stores a maximum value Vmax (S) of lightness V with the saturation S in the reproduction HSV color space expanded by adding the fourth color as a variable. That is, the signal processing unit 120 stores the value of the maximum value Vmax (S) of the brightness V for each coordinate (value) of the saturation S and the hue H for the three-dimensional shape of the reproduction HSV color space shown in FIG. ing.

  Since the input signal SRGB is a signal having input signal values corresponding to the first primary color, the second primary color, and the third primary color, the HSV color space of the input signal SRGB has a cylindrical shape, that is, FIG. The same shape as the cylindrical portion of the reproduction HSV color space shown in FIG. Therefore, the output signal SRGBW can be calculated as an expanded image signal obtained by expanding the input signal SRGB with respect to the reproduction HSV color space. This expanded image signal is expanded by an expansion coefficient α determined by comparing the lightness levels in the reproduction HSV color space. By expanding the signal level of the input image signal by the expansion coefficient α, the value of the fourth subpixel 202W can be increased, and the luminance of the entire image can be improved. At this time, since the luminance of the entire image is improved by the expansion coefficient α, the luminance of the light source device 300 is reduced to 1 / α, so that it is possible to display with the same luminance as the input signal SRGB.

  Next, the expansion of the input signal SRGB will be described.

In the signal processing unit 120, when χ is a constant depending on the display device 100, the (p, q) -th pixel (or the first sub-pixel 202R, the second sub-pixel 202G, the third sub-pixel 202B, X1 _{(p, q)} that is the output signal of the first subpixel 202R, X2 _{(p, q)} that is the output signal of the second subpixel 202G, and X3 that is the output signal of the third subpixel 202B _{(p, q)} can be expressed as follows using the expansion coefficient α and the constant χ. χ will be described later.

X1 _{(p, q)} = α · x1 _{(p, q)} −χ · X4 _{(p, q)} (1)

X2 _{(p, q)} = α · x2 _{(p, q)} −χ · X4 _{(p, q)} (2)

X3 _{(p, q)} = α · x3 _{(p, q)} −χ · X4 _{(p, q)} (3)

The output signal value X4 _{(p, q)} can be obtained based on the product of Min _{(p, q)} and the expansion coefficient α. Min _{(p, q)} is the input signal value x1 of the first subpixel 202R _{(p, q),} the input signal value x2 of the second subpixel 202G _{(p, q),} the input signal value of the third sub-pixel 202B x3 _This is the minimum value of _{(p, q)} . Specifically, the output signal value X4 _{(p, q)} can be obtained based on the following equation (4).

X4 _{(p, q)} = Min _{(p, q)} · α / χ (4)

In Equation (4), the product of Min _{(p, q)} and the expansion coefficient α is divided by χ, but the present invention is not limited to this. The expansion coefficient α is determined for each image display frame.

  Hereinafter, these points will be described.

In general, the (p, q) in the pixel of the second input signal value x1 of the first subpixel 202R _{(p, q),} the input signal value x2 of the second subpixel 202G _{(p, q),} third sub-pixel 202B Saturation S _{(p, q)} and lightness V (S) _{(p, q)} in the HSV color space of the cylinder based on the input signal SRGB including the input signal value x3 _{(p, q)} of 5) and (6).

S _{(p, q)} = (Max _{(p, q)} −Min _{(p, q)} ) / Max _{(p, q)} (5)

V (S) _{(p, q)} = Max _{(p, q)} (6)

Incidentally, Max _{(p, q)} is the input signal value x1 of the first subpixel 202R _{(p, q),} the input signal value x2 of the second subpixel 202G _{(p, q),} the input signal of the third sub-pixel 202B It is the maximum value among the values x3 _{(p, q)} . Min _{(p, q)} is the minimum value of the input values of the three sub-pixels as described above. The saturation S can take a value from 0 to 1, and the lightness V (S) can take a value from 0 to (2 ⁿ −1). n is the number of display gradation bits.

Here, no color filter is disposed in the fourth sub-pixel 202W that displays white. When the fourth sub-pixel 202W displaying the fourth color is irradiated with the same light source lighting amount, the first sub-pixel 202R displaying the first primary color, the second sub-pixel 202G displaying the second primary color, and the third Brighter than the third sub-pixel 202B displaying the primary color. A signal having a value corresponding to the maximum signal value of the output signal of the first subpixel 202R is input to the first subpixel 202R, and the signal value corresponding to the maximum signal value of the output signal of the second subpixel 202G is input to the second subpixel 202G. When the signal having a value is input and a signal having a value corresponding to the maximum signal value of the output signal of the third sub-pixel 202B is input to the third sub-pixel 202B, the first pixel 201 or the group of the pixels 201 includes The luminance of the aggregate of the subpixel 202R, the second subpixel 202G, and the third subpixel 202B is BN _1-3 . Further, when the fourth luminance subpixel 202W when the signal having a value corresponding to the maximum signal value of the output signal of the fourth sub-pixel 202W included in the group of pixels 201 or the pixel 201 is input to the BN ₄ Suppose. That is, the first sub-pixel 202R, the second sub-pixel 202G, the maximum brightness of the white by a set of third sub-pixels 202B is displayed, the brightness of the white is represented by BN _1-3. Then, the constant χ depending on the display device 100 is expressed by χ = BN ₄ / BN _1-3 .

By the way, when the output signal value X4 _{(p, q)} is given by the above equation (4), the maximum value Vmax (S) of the brightness V with the saturation S in the reproduction HSV color space as a variable is (7) and (8).

If S ≦ S ₀ ,
Vmax (S) = (χ + 1) · (2 ⁿ −1) (7)

If S ₀ <S ≦ 1,
Vmax (S) = (2 ⁿ −1) · (1 / S) (8)
Here, S ₀ = 1 / (χ + 1).

  The maximum value Vmax (S) of the lightness V with the saturation S in the reproduction HSV color space obtained by adding the fourth color as a variable is, for example, a kind of lookup for the signal processing unit 120. Stored as a table. Alternatively, the maximum value Vmax (S) of the lightness V with the saturation S in the reproduction HSV color space as a variable is obtained in the signal processing unit 120 each time.

  The expansion coefficient α is a coefficient for expanding the lightness V (S) in the HSV color space to the reproduction HSV color space, and can be expressed by the following equation (9).

  α (S) = Vmax (S) / V (S) (9)

  In the expansion calculation, for example, the expansion coefficient α is determined based on α (S) obtained for the plurality of pixels 201.

  Next, signal processing using the expansion coefficient α in the signal processing unit 120 will be described. In the following processing, the luminance of the first primary color displayed by (first subpixel 202R + fourth subpixel 202W) and the luminance of the second primary color displayed by (second subpixel 202G + fourth subpixel 202W). , (The third subpixel 202B + the fourth subpixel 202W) is performed so as to maintain the luminance ratio of the third primary color displayed. In addition, the color tone is maintained (maintained). Further, the gradation-luminance characteristics (gamma (γ) characteristics) are maintained (maintained). If any of the input signal values is zero or small in any pixel 201 or group of pixels 201, the expansion coefficient α is calculated without including such pixel 201 or group of pixels 201. You may do that.

Processing in the image analysis unit 121 will be described. The image analysis unit 121 obtains the saturation S and the brightness V (S) in each pixel 201 based on the input signal SRGB of the pixel 201. Specifically, using the input signal value x1 _{(p, q)} , the input signal value x2 _{(p, q)} , and the input signal value x3 _{(p, q)} in the (p, q) -th pixel, 5) and S _{(p, q)} and V (S) _{(p, q)} are obtained from (6). This process is performed for all pixels. As a result, a set of (S _{(p, q)} , V (S) _{(p, q)} ) is obtained for the number of pixels, and the expansion coefficient α is calculated based on Expression (9).

  Next, signal processing by the signal processing unit 120 including such a functional configuration will be described with reference to FIG.

  FIG. 9 is a flowchart of signal processing executed by a signal processing unit included in the display device according to the second embodiment.

  In the display device 100, processing is started for each image display frame, and the input signal SRGB is input to the signal processing unit 120 via the image input unit 110.

[Step S1] The signal processing unit 120 acquires an input signal SRGB.
[Step S2] Gamma conversion is performed on the input signal SRGB to linearize the input signal SRGB.

[Step S3] The image analysis unit 121 acquires the linearized input signal SRGB and performs image analysis processing. In the image analysis processing, an expansion coefficient α for converting the luminance of the pixel 201 is calculated for each pixel 201 according to the input signal SRGB, and based on the range set according to the input signal SRGB from the calculated expansion coefficient α. To determine the expansion coefficient α. Details of the image analysis processing will be described later.
The light source control unit 123 calculates the luminance information of the light source device 300 based on the input signal SRGB and the expansion coefficient α determined by the image analysis unit 121, and determines the lighting amount of the sidelight light source 302.

  [Step S4] The image processing unit 122 performs output signal SRGBW generation processing for each pixel from the input signal SRGB. In the output signal SRGBW generation process, the output signal SRGBW is generated from the input signal SRGB based on the expansion coefficient α determined by the image analysis process.

  [Step S5] The image processing unit 122 performs inverse gamma conversion on the output signal SRGBW and outputs the result to the image display panel driving unit 400.

  [Step S6] Display is performed. The image display panel driving unit 400 outputs the output signal SRGBW to the image display panel 200, and the light source device driving unit 500 drives the light source 303 of the light source device 300 based on the determined lighting amount.

  By such processing, an image of the input signal SRGB is reproduced on the image display panel 200.

  Next, details of the image analysis processing (step S3) executed in the signal processing (FIG. 9) will be described with reference to FIG. 10 together with FIG.

  FIG. 10 is a flowchart of image analysis processing executed by the signal processing unit included in the display device according to the second embodiment.

  The image analysis unit 121 acquires the input signal SRGB and starts the following processing.

  [Step S11] The conversion coefficient determination unit 121b calculates an expansion coefficient α for converting the luminance of the pixel 201 for each pixel 201 in accordance with the input signal SRGB.

  [Step S12] The image comparison unit 121c selects a selected pixel (p, q) that satisfies a predetermined condition based on the read input signal SRGB. Note that the predetermined condition may be a condition for causing the pixel interval of the selected pixels to be a predetermined pixel interval such as 4 pixels, 8 pixels, 16 pixels, or the like.

  [Step S13] The image comparison unit 121c detects and holds the expansion coefficient α of the selected selected pixel (p, q).

[Step S14] The image comparison unit 121c determines whether or not selection of all pixels satisfying a predetermined condition has been completed.
The image comparison unit 121c proceeds to the process of step S15 when the selection of all the pixels satisfying the predetermined condition is not completed, and proceeds to the process of step S16 when the selection of all the pixels satisfying the predetermined condition is completed. Proceed to processing.

  [Step S15] The image comparison unit 121c selects different pixels 201 that satisfy a predetermined condition.

  [Step S16] The image comparison unit 121c counts the number N of pixels having an expansion coefficient α smaller than the reference value (α1) held by the threshold holding unit 121a in the expansion coefficients α of all the pixels 201 that satisfy a predetermined condition. .

[Step S17] The image comparison unit 121c compares the pixel count N counted in step S16 with the threshold pixel count Na.
As a result of the comparison by the image comparison unit 121c, the threshold setting unit 121d executes the process of step S18 if the pixel number N is equal to or greater than the threshold pixel number Na, and if the pixel number N is less than the threshold pixel number Na, the step The process of S19 is executed.

[Step S18] The threshold setting unit 121d sets the minimum value of the range for determining the expansion coefficient α to α _min from the expansion coefficient α detected and held in Step S13.

  [Step S19] The threshold setting unit 121d sets the minimum value of the range for determining the expansion coefficient α to the setting value α1, from the expansion coefficient α detected and held in Step S13.

  [Step S20] The conversion coefficient determination unit 121b determines the expansion coefficient α from the expansion coefficient α detected and held in Step S13 based on the range set in Step S18 or Step S19.

By performing the above processing procedure, the minimum value is set to α _min when the pixel number N of the expansion coefficient α smaller than the minimum value α1 in the image based on the input signal SRGB is equal to or larger than the threshold pixel number Na. For this reason, the luminance of each pixel also changes with the change of the gradation value in the input signal SRGB, and the deterioration of the image quality of the display image on the image display panel 200 can be suppressed.

[Third Embodiment]
In the third embodiment, various aspects of the range for the image analysis unit 121 of the second embodiment to determine the expansion coefficient α for generating the output signal from the calculated expansion coefficient α are shown in FIG. Will be described.

FIG. 11 is a diagram for explaining a set value according to the number of pixels based on the expansion coefficient of the image analysis process executed by the signal processing unit included in the display device according to the third embodiment.
FIGS. 11A to 11C correspond to Examples 1 to 3 described later, and the image comparison unit 121c uses a reference value as a reference for a pixel to be counted, and a counted pixel. The threshold value pixel number, which is the number of pixels used for comparison with the number N, and the threshold value setting unit 121d indicate a setting value that is a value set as the minimum value of the conversion coefficient in accordance with the comparison result of the image comparison unit 121c. In addition, the numerical value described in FIG. 11 is an example, Comprising: It is not limited to these.

Example 1
In the first embodiment, a case where the reference value of the expansion coefficient α corresponding to the pixel to be counted is different from the set value of the expansion coefficient α set as the minimum value will be described with reference to FIG.
In the second embodiment, when the number N of pixels with an expansion coefficient α smaller than α1 (1.2) is less than the threshold pixel number Na (1200), the minimum range for determining the expansion coefficient α Α1 (1.2) was set as the value (set value).

In the first embodiment, as shown in FIG. 11A (middle), the number N of pixels having an expansion coefficient α smaller than a reference value α1a (1.4) larger than α1 is less than the threshold pixel number Na1 (1500). In some cases, the set value α1 (1.2) is set as the minimum value of the range for determining the expansion coefficient α.
As described above, when the reference value is larger than the set value, the range of the expansion coefficient α of the pixel to be counted is widened, so that the occurrence of luminance collapse can be appropriately prevented.

Also, as shown in FIG. 11A (lower), when the number N of pixels with an expansion coefficient α smaller than the reference value α1 (1.2) is less than the threshold pixel number Na (1200), the expansion coefficient α The set value α1a (1.4) is set as the minimum value of the range for determining the value.
As described above, when the reference value is smaller than the set value, the range of the expansion coefficient α of the pixel to be counted is narrowed, so that the power consumption can be reduced.

(Example 2)
In Example 2, a plurality of reference values of the expansion coefficient α corresponding to the pixel to be counted are provided, and the setting value of the expansion coefficient α is associated with the threshold pixel number for each reference value. A description will be given using B).

  For example, the image comparison unit 121c counts the number N of pixels having an expansion coefficient α smaller than a reference value α1 (for example, 1.1) from the expansion coefficients α of all the pixels 201 that satisfy a predetermined condition. The pixel comparison unit 121c sets the setting value α1 as the minimum value when the pixel number N is less than the threshold pixel number N1 (for example, 1000).

  Further, the image comparison unit 121c determines that the pixel number N of the expansion coefficient α smaller than the reference value α2 (for example, 1.2) from the expansion coefficient α of all the pixels 201 that satisfy the predetermined condition is the threshold pixel number N2 (for example, If it is less than 1200), the set value α2 is set as the minimum value.

  Similarly, when the image comparison unit 121c similarly determines that the number N of pixels having an expansion coefficient α smaller than the reference value αn is less than the threshold pixel number Nn among the expansion coefficients α of all the pixels 201 that satisfy a predetermined condition. The set value αn is set as the minimum value.

  Thus, by setting a plurality of reference expansion coefficients α for the expansion coefficient α to be counted, it is possible to reduce power consumption while appropriately preventing occurrence of luminance collapse.

In the second embodiment, the case where the threshold pixel number is provided for each reference value is described as an example. However, the present invention is not limited to this case, and only one threshold pixel number may be provided.
Further, when it is determined that the input image signal is less than the threshold pixel number Na with respect to a plurality of reference values, the image comparison unit 121c sets a setting value corresponding to the reference value that is most effective in reducing power consumption. The minimum value may be set. For example, with respect to the input signal, the number of pixels whose conversion coefficient is less than the reference value α1 is less than the threshold number of pixels N1 corresponding to the reference value α1, and the number of pixels whose conversion coefficient is less than the reference value α2 is the reference value. When the number of threshold pixels corresponding to α2 is less than N2, the set value α2 corresponding to the reference value α2 may be set as the minimum value of the conversion coefficient when generating the output signal.

(Example 3)
In the third embodiment, a case where a plurality of threshold pixel numbers are associated with the reference value of the expansion coefficient α corresponding to the pixel to be counted will be described with reference to FIG.

For example, the image comparison unit 121c counts the number N of pixels having an expansion coefficient α that is smaller than α1 (for example, 1.1) and larger than α _min from the expansion coefficient α of all the pixels 201 that satisfy a predetermined condition. The pixel comparison unit 121c sets α1 as the setting value when the pixel number N is less than the threshold pixel number N1 (for example, 1000).

In addition, when the image comparison unit 121c determines that the number of pixels N of the expansion coefficient α that is smaller than α1 and larger than α _min is less than the threshold pixel number N2 (for example, 800) from the expansion coefficients α of all the sampled pixels 201. Sets α2 as a set value.

Similarly, when the image comparison unit 121c has a pixel number N of the expansion coefficient α smaller than α1 and larger than α _min in the expansion coefficient α of all the sampled pixels 201 is less than the threshold pixel number Nn. , Αn is set as a set value.

  Thus, by finely setting the threshold pixel number with respect to the reference value of the expansion coefficient α to be counted, it is possible to reduce power consumption while appropriately preventing occurrence of luminance collapse.

[Fourth Embodiment]
In the fourth embodiment, a determination method different from the determination method used when α1 or _αmin is set as the minimum value in the second embodiment will be described with reference to FIG. 12 together with FIG.

FIG. 12 is a diagram for explaining a minimum value determination method executed by the signal processing unit included in the display device according to the fourth embodiment.
12A shows a histogram representing the number of pixels (solid line) and the number of weighted pixels (broken line) for the expansion coefficient, and FIG. 12B shows weighting for the number of pixels.

  The image comparison unit 121c counts the number of pixels N equal to or less than the reference value (α1) of the α value among the expansion coefficients α calculated by the conversion coefficient determination unit 121b for each expansion coefficient α, and the result is shown in FIG. A histogram representing the number of pixels for each expansion coefficient α as shown by a solid line is generated.

For example, as in the case of the second embodiment, as shown in FIG. 12B, the expansion coefficient α below the reference value (α1 = 1.2) is 1.2, 1.1, 1 0.0, and the number of pixels is na, nb, and nc.
Here, weights β1, β2, and β3 are assigned to such pixel numbers na, nb, and nc, respectively.

For example, in the above formula _{(B), α min = 1} , α max = 2, if it is [alpha] 1 = 1.2, in the range of [alpha] 1 and alpha _min, expansion coefficient alpha is larger the difference between the [alpha] 1, [alpha] 1 Since the rate of change with respect to increases, the degree of influence increases accordingly. Therefore, in order to reflect the magnitude of such a change rate, the image comparison unit 121c adds the weights β1, β2, and β3 to the pixel numbers na, nb, and nc, respectively (weighted pixel number). Is calculated (FIG. 12B), and the weighted pixel number is reflected in the histogram (broken line in FIG. 12A). Note that the values of the weights β1, β2, and β3 are set so as to be proportional to the difference between the expansion coefficients α and α1. That is, for example, in the case of FIG. 12, as the difference between the expansion coefficients α and α1 increases, the values of the weights β1, β2, and β3 (β1 = 1, β2 = 1.5, β3 = 2) increase. did.

  The image comparison unit 121c compares the sum of the weighted pixel numbers with a predetermined value (evaluation value) set in advance. The threshold setting unit 121d sets the minimum value of the range used for determining the conversion coefficient, as in the second embodiment, according to the comparison result between the number of weighted pixels of the image comparison unit 121c and the predetermined value.

[Fifth Embodiment]
In the fifth embodiment, a case will be described in which the display device 100 according to the second embodiment performs display by split drive control.

First, the display by the division | segmentation drive control of the display apparatus 100 is demonstrated using FIG.
FIG. 13 is a diagram for explaining display by split drive control of the display device according to the fifth embodiment.

In the display device 100, the light source 303 is positioned on the lower side in FIG. 13, for example, and one image to be displayed on the display surface can be divided into, for example, four blocks A11 to A22. At this time, the light source device 300 controls the luminance for each block by adjusting the lighting amount of the light source 303. As a result, the luminance of the light source device 300 can be lowered in a block with low luminance of the image, and power consumption can be reduced.
Even in the display device 100 that displays by such divided driving, it is possible to perform image analysis processing on each block in the same manner as in the second embodiment. The image analysis process will be described with reference to FIG.

FIG. 14 is a flowchart of image analysis processing executed by the signal processing unit included in the display device according to the fifth embodiment.
In the display device 100, processing is started for each image display frame, and the input signal SRGB is input to the signal processing unit 120 via the image input unit 110.
When the signal processing unit 120 acquires the input signal SRGB, performs gamma conversion on the input signal SRGB, and linearizes the input signal SRGB, the following image analysis processing is executed.

  [Step S40] The image analysis unit 121 initializes block numbers i and j (i = 1, j = 1) that specify blocks to be processed.

  [Step S41] The conversion coefficient determination unit 121b reads the input signal SRGB for the pixels included in the designated block (i, j), and converts the luminance of the pixel 201 for each pixel 201 in accordance with the input signal SRGB. The expansion coefficient α is calculated.

  [Step S42] The image comparison unit 121c selects a selected pixel (p, q) that satisfies a predetermined condition based on the read input signal SRGB.

  [Step S43] The image comparison unit 121c detects and holds the expansion coefficient α of the selected selected pixel (p, q).

[Step S44] The image comparison unit 121c determines whether or not selection of all the pixels 201 satisfying a predetermined condition in the designated block (i, j) is completed.
The image comparison unit 121c proceeds to the process of step S45 when the selection of all the pixels satisfying the predetermined condition is not completed, and proceeds to the process of step S46 when the selection of all the pixels satisfying the predetermined condition is completed. Proceed to processing.

  [Step S45] The image comparison unit 121c selects another pixel 201 that satisfies a predetermined condition.

  [Step S46] The image comparison unit 121c is smaller than the reference value (α1) held by the threshold holding unit 121a in the expansion coefficient α of all the pixels 201 that satisfy the predetermined condition in the designated block (i, j). The number N of pixels of the expansion coefficient α is counted.

[Step S47] The image comparison unit 121c compares the pixel count N counted in step S46 with the threshold pixel count Na.
As a result of the comparison by the image comparison unit 121c, the threshold setting unit 121d executes the process of step S48 if the pixel number N is equal to or greater than the threshold pixel number Na, and if the pixel number N is less than the threshold pixel number Na, the step The process of S49 is executed.

[Step S48] The threshold value setting unit 121d sets α _min to the minimum value of the range for determining the expansion coefficient α from the expansion coefficient α detected and held in step S43.

  [Step S49] The threshold setting unit 121d sets α1, which is a set value, to the minimum value of the range for determining the expansion coefficient α from the expansion coefficient α detected and held in step S43.

  [Step S50] The conversion coefficient determination unit 121b determines the number of pixels in the specified block (i, j) based on the range set in step S48 or step S49 from the expansion coefficient α of each pixel detected and held in step S43. Determine the expansion coefficient α.

[Step S51] The image analysis unit 121 compares the block number (i, j) with the final block numbers I and J to determine whether the block is the final block.
The image analysis unit 121 determines that the block is the final block if i = I and j = J. If it is the last block, the expansion coefficient α of all the blocks has been calculated, and the process is terminated. If it is not the final block, the image analysis unit 121 proceeds to the process of step S52.

  [Step S52] The image analysis unit 121 increments the block number (i, j) by 1, and returns to the process of step S41.

By performing the above processing procedure, the minimum value is obtained when the number of pixels N of the expansion coefficient α smaller than α1 is equal to or greater than the threshold number of pixels Na in the image in the designated block (i, j) based on the input signal SRGB. Α _min is set to. For this reason, the luminance of each pixel also changes with the change of the gradation value in the input signal SRGB, and the deterioration of the image quality of the display image on the image display panel 200 can be suppressed.

  Also, when the number of pixels N of the expansion coefficient α smaller than α1 is smaller than the threshold pixel number Na in the image in the designated block (i, j) based on the input signal SRGB, α1 is set as the minimum value. In this case, the display device 100 can reduce power consumption.

  In addition, the third embodiment and the fourth embodiment can be applied to the processes of steps S46 and S47 of the fifth embodiment.

  In the first to fifth embodiments, the image comparison unit 121c selects only pixels that satisfy a predetermined condition, detects and holds a conversion coefficient, and is equal to or lower than a predetermined threshold value in the selected pixel. Although it was decided to determine whether or not to change the conversion coefficient based on the number of pixels, the present invention is not limited to this. It may be determined whether to change the conversion coefficient. In the first to fifth embodiments, conversion coefficients are calculated for all pixels, and then conversion coefficients of pixels that satisfy a predetermined condition are detected and held. However, the present invention is not limited to this. Only the pixels that satisfy the condition may be selected to calculate the conversion coefficient.

In the first to fifth embodiments, the light source control unit 123 generates the light source control signal SBL and the image processing unit 122 outputs the output signal SRGBW based on the conversion coefficient (expansion coefficient α) calculated by the image analysis unit 121. However, the light source control signal SBL and the output signal SRGBW may be subjected to further correction processing.
For example, the light source control unit 123 includes a light source data storage unit that stores luminance distribution information of a plurality of light sources 303, and the light source control unit 123 stores the conversion coefficient calculated by the image analysis unit 121 and the light source data storage unit. Based on the luminance distribution information, the luminance information is calculated for each pixel or for a plurality of regions including a plurality of pixels when the lighting is performed with the lighting amount (PWM value) determined by the conversion coefficient.
The image processing unit 122 outputs an output signal based on the conversion coefficient calculated by the image analysis unit 121 and the luminance distribution information stored in the light source data storage unit included in the light source control unit 123 received via the image analysis unit 121. SRGBW is generated.
In this way, it is possible to generate the light source control signal SBL and the output signal SRGBW reflecting the luminance distribution information of each light source 303 as well as the gradation and saturation due to the input signal.

Furthermore, the conversion coefficient determination unit 121b may include a light source data storage unit that stores luminance distribution information of the plurality of light sources 303. The conversion coefficient determination unit 121b calculates a conversion coefficient (1 / β) for each pixel or each region including a plurality of pixels based on the input signal SRGB and the luminance distribution information. The image comparison unit 121c compares whether the calculated conversion coefficient (1 / β) has a conversion coefficient equal to or greater than the first threshold value (1 / β1) or whether the number of regions is equal to or greater than the evaluation value. The threshold value setting unit 121d sets the second threshold value (1 / β2) larger than the first threshold value (1 / β1) when the value is equal to or higher than the evaluation value, and sets the first threshold value (1) when the value is less than the evaluation value. / Β1) is set. The conversion coefficient determination unit 121b determines the conversion coefficient based on the set threshold value.
Then, the light source control unit 123 generates the light source control signal SBL based on the determined conversion coefficient (1 / β), and the image processing unit 122 outputs the output signal SRGBW based on the inverse number (β) of the determined conversion coefficient. Is generated.

  The above processing functions can be realized by a computer. In that case, a program describing the processing contents of the functions that the display device should have is provided. By executing the program on a computer, the above processing functions are realized on the computer. The program describing the processing contents can be recorded on a computer-readable recording medium. Examples of the computer-readable recording medium include a magnetic storage device, an optical disk, a magneto-optical recording medium, and a semiconductor memory. Examples of the magnetic storage device include a hard disk drive (HDD), a flexible disk (FD), and a magnetic tape. Optical discs include DVD (Digital Versatile Disc), DVD-RAM, CD (Compact Disc) -ROM, CD-R (Recordable) / RW (ReWritable), and the like. Magneto-optical recording media include MO (Magneto-Optical disk).

  When distributing the program, for example, a portable recording medium such as a DVD or a CD-ROM in which the program is recorded is sold. It is also possible to store the program in a storage device of a server computer and transfer the program from the server computer to another computer via a network.

  The computer that executes the program stores, for example, the program recorded on the portable recording medium or the program transferred from the server computer in its own storage device. Then, the computer reads the program from its own storage device and executes processing according to the program. The computer can also read the program directly from the portable recording medium and execute processing according to the program. In addition, each time a program is transferred from a server computer connected via a network, the computer can sequentially execute processing according to the received program.

  Further, at least a part of the above processing functions can be realized by an electronic circuit such as a DSP (Digital Signal Processor), an ASIC (Application Specific Integrated Circuit), or a PLD (Programmable Logic Device).

  In the present embodiment, the case of a liquid crystal display device has been illustrated, but as another application example, for example, a self-luminous display device such as an organic LED (OLED), or an electronic paper display having an electrophoretic element or the like Any flat panel display device such as a device may be used. Moreover, it cannot be overemphasized that it can apply, without specifically limiting from a small size to a large size. Further, the liquid crystal display device is not limited to a transmission type, and may be a reflection type. In the liquid crystal display device in this case, the light source device and the configuration relating to the control of the light source device are not required, and the luminance of the image can be improved by increasing the minimum value of the α value.

  In the category of the idea of the present invention, those skilled in the art can conceive various changes and modifications, and it is understood that these changes and modifications also belong to the scope of the present technology. For example, those in which the person skilled in the art appropriately added, deleted, or changed the design of the above-described embodiments, or added the process, omitted, or changed the conditions are also included in the present technology. As long as the gist is provided, it is included in the scope of the present technology.

  In addition, other functions and effects brought about by the aspects described in the present embodiment, which are apparent from the description of the present specification, or can be appropriately conceived by those skilled in the art are naturally understood to be brought about by the present invention. The

  DESCRIPTION OF SYMBOLS 1 ... Display apparatus, 2 ... Control part, 3 ... Image display panel part, 4 ... Illumination part

Claims (9)

From the input image signal, an output image signal in which the luminance of the pixel is converted using the conversion coefficient in which the first threshold is set is generated,
Determining whether the image based on the input image signal is a specific image;
A control unit that changes the first threshold to a second threshold different from the first threshold when the image is the specific image;
An image display panel for displaying an image based on the output image signal;
A display device. The specific image includes pixels of the transform coefficient outside the first threshold;
The display device according to claim 1. The controller is
Determining whether an image based on the input image signal is the specific image according to an evaluation value related to the pixel of the conversion coefficient outside the first threshold;
The display device according to claim 2. The evaluation value is the number of pixels of the conversion coefficient outside the first threshold.
The display device according to claim 3. The evaluation value is obtained by weighting the number of pixels of the conversion coefficient outside the first threshold according to a difference from the first threshold to the conversion coefficient outside the first threshold.
The display device according to claim 3. The second threshold is smaller than the first threshold;
The display device according to claim 1. The controller is
For each of a plurality of different threshold values, it is determined whether or not the specific image satisfies any evaluation value according to the evaluation value related to the pixel of the conversion coefficient outside the threshold value, and the threshold value corresponding to the evaluation value satisfied by the specific image is determined. 2 threshold values,
The display device according to claim 1. The controller is
Changing the first threshold to one of a plurality of different thresholds outside the first threshold according to the determination result of the specific image based on the number of pixels of the conversion coefficient outside the first threshold;
The display device according to claim 1. In a display method of a display device including a control unit and an image display panel,
The control unit is
From the input image signal, an output image signal in which the luminance of the pixel is converted using the conversion coefficient in which the first threshold is set is generated,
Determining whether the image based on the input image signal is a specific image;
In the case of the specific image, the first threshold is changed to a second threshold different from the first threshold,
The image display panel is
Displaying an image based on the output image signal;
Display method.

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