JP7380299B2 - Display controller and display device - Google Patents

Description

The present invention relates to a display control device and a display device that reduce radiation noise caused by differences in gradation values between pixels in a display panel including a pixel group made up of self-luminous elements.

Conventionally, a display device includes, for example, a display panel and a control unit including an IC (integrated circuit) for driving the display panel, and displays various images on the display panel based on a video signal converted into digital data. It has been known. This video signal corresponds to each pixel of a pixel group constituting the display panel, and is transmitted through a signal line in the driving IC. If the transmission speed of the video signal and the change in the bit value of the video signal in the driving IC are high, unintended radiation noise may occur. Radiation noise needs to be reduced because it can cause malfunctions in other electronic devices and electronic components.

An example of a display device that performs display control to reduce radiation noise is the one described in Patent Document 1. The display device described in Patent Document 1 compares a video signal of a first luminescent color and a video signal of a second luminescent color to determine whether a predetermined condition is satisfied, and in the case of an affirmative determination, displays a video signal of a first luminescent color and a video signal of a second luminescent color. The configuration is such that the values of some bits of the video signal of the second luminescent color are inverted. This display device inverts some of the bits in the video signal of the second luminescent color when a predetermined condition is met, thereby reducing the frequency with which changes in bits in the same direction appear simultaneously. Radiated noise is reduced.

JP 2017-60046 Publication

Incidentally, in recent years, in the field of displays, more precise graphics have been required, and display panels whose pixels are composed of self-luminous elements, such as organic light emitting diodes (OLEDs), have higher display quality than liquid crystal panels. It is seen as promising.

Therefore, the present inventors have developed a display device with reduced radiant noise while further improving display quality by using a display panel including a self-emitting element (for example, an OLED panel) and the above-described method of reducing radiant noise. I thought it would be possible to achieve this.

However, as a result of extensive research, we found that when using an OLED panel, in addition to radiation noise caused by the transmission of video signals in the driving IC, differences in current values between adjacent pixels among the pixel groups that make up the OLED panel It was found that radiation noise was caused by

Specifically, liquid crystal panels that use a common backlight as a light source use a common light source and are configured to control the orientation of liquid crystal molecules in each pixel, so even if the brightness of each pixel is increased, Large current changes are less likely to occur between adjacent pixels. On the other hand, in OLED panels where each pixel emits light by itself, a current is generated individually in each pixel, and the higher the brightness, the higher the current value (gradation value), so there is a large current change between adjacent pixels. may occur. At this time, in the OLED panel, if the video signal is high speed, the above-mentioned large current change will also occur at high speed, and radiation noise may occur due to the difference in current value between adjacent pixels. The above method for reducing radiation noise can reduce radiation noise caused by high-speed transmission of video signals in a driving IC, but cannot reduce radiation noise in a display panel whose pixels are self-luminous elements.

In view of the above points, the present invention aims to reduce radiation noise in a display panel equipped with a pixel group made of self-luminous elements, particularly radiation noise caused by a difference in current value between adjacent pixels in the pixel group. purpose.

In order to achieve the above object, the display control device according to claim 1 is configured to adjust the difference in gradation value between adjacent main pixels among a group of main pixels made of self-luminous elements constituting the display panel (2). This is a display control device that suppresses electromagnetic radiation noise caused by noise, and includes a video processing circuit (31) that generates a first video signal to be input to a display panel, and a video processing circuit (31) that generates an adjacent main video signal based on the first video signal. A signal determination unit (32) determines whether the difference in tone values between pixels satisfies a predetermined condition, and a signal determination unit (32) determines whether the difference in tone values between adjacent main pixels satisfies a predetermined condition based on the determination result of the signal determination unit. a signal converter (33) that converts at least a portion of the first video signal to generate a second video signal, and a display panel that converts the first video signal or the second video signal to a video output section (35) for outputting to the main pixel, the main pixel is made up of a plurality of sub-pixels emitting different colors, and the signal determination section selects one of the main pixels from the group based on the first video signal. The signal conversion unit determines whether or not the gradation difference, which is the difference between one gradation value and the other gradation value of adjacent main pixels that are adjacent to each other, exceeds a predetermined threshold, and the signal conversion unit determines whether or not the gradation value is determined by the signal determination unit. When it is determined that the tone difference exceeds a predetermined threshold, at least a portion of the adjacent main pixel whose tone difference exceeds the threshold in the first video signal is converted to generate a second video signal. do.
Further, the display control device according to claim 2 is characterized in that electromagnetic electromagnetic A display control device for suppressing radiation noise, which includes a video processing circuit (31) that generates a first video signal to be input to a display panel; a signal determination unit (32) that determines whether the condition is satisfied; and a signal determination unit (32) that determines whether or not the condition is satisfied; a signal converter (33) that converts the image signal and generates a second video signal; and a video output unit (35) that outputs the first video signal or the second video signal to the display panel . consists of multiple sub-pixels that emit light of different colors, the image displayed on the display panel at a certain moment is the first frame image, and the image displayed on the display panel at the moment after the first frame image is the first frame image. Assuming that there are two frames of video and the average value of the gradation values of the pixel group is the gradation value of the entire video, the signal determination unit determines the gradation value of the entire video of the first frame and the gradation value of the entire video based on the first video signal. The signal converter determines whether the gradation difference of the entire video, which is the difference between the gradation values of the entire video of two frames, exceeds a predetermined threshold, and the signal converter determines whether the gradation difference of the entire video is If it is determined that the threshold is exceeded, a second video signal is generated in which a new frame of video is inserted between the first frame of video and the second frame of video, and a new frame of video is generated. The overall gradation value is intermediate between the gradation value of the entire video of the first frame and the gradation value of the entire video of the second frame.

As a result, the display control device according to claim 1 can determine the distance between adjacent main pixels of the pixel group based on the first video signal input to the display panel including the pixel group consisting of main pixels each made of a self-emitting element. If the difference in gradation values satisfies a predetermined condition, the first video signal is converted into a second video signal so that the difference in gradation values is less than a predetermined value . Therefore, a difference in gradation value exceeding a predetermined value is suppressed from occurring in the pixel group constituting the display panel, and electromagnetic radiation noise in the display panel is reduced.
Furthermore, the display control device according to claim 2 reduces consumption between frames by interpolating an inserted frame between the consecutive first frame and second frame, which is a halftone of the video in these frames. Reduce the amount of power change. Therefore, it is possible to reduce electromagnetic radiation noise in the display panel due to the magnitude of the change in power consumption between frames.

The display device according to claim 3 further includes a display panel (2) including a pixel group consisting of a main pixel made of a self-luminous element, and a video processing circuit (31) that generates a first video signal input to the display panel. ), a signal determination unit (32) that determines whether the difference in gradation values of the pixel groups satisfies a predetermined condition based on the first video signal; a signal converter (33) that converts at least a part of the first video signal to generate a second video signal so that the difference in gradation values between main pixels is less than a predetermined value; or a second video signal to the display panel, the main pixel is made up of a plurality of sub-pixels that emit light of different colors, and the signal determination section is configured to output the first video signal or the second video signal to the display panel. Based on the signal, it is determined whether the gradation difference, which is the difference between the gradation value of one of the adjacent main pixels that are adjacent to each other in the pixel group, and the gradation value of the other, exceeds a predetermined threshold. If the signal determining unit determines that the gradation difference exceeds the threshold, the signal converting unit converts at least the portion of the adjacent main pixel in which the gradation difference exceeds the threshold of the first video signal. Then, a second video signal is generated.
The display device according to claim 4 includes: a display panel (2) including a pixel group consisting of main pixels each made of a self-luminous element; and a video processing circuit (31) that generates a first video signal to be input to the display panel. , a signal determination unit (32) that determines whether the difference in gradation values between frames of consecutive images of the pixel group satisfies a predetermined condition based on the first video signal; and a determination result of the signal determination unit. a signal converter (33) that converts at least a part of the first video signal to generate a second video signal so that the difference in gradation values is less than a predetermined value based on the first video signal; a video output section (35) that outputs a video signal or a second video signal to the display panel, the main pixel is composed of a plurality of sub-pixels that emit light of different colors, and the main pixel is configured to output an image displayed on the display panel at a certain moment. is the first frame image, the image displayed on the display panel at the moment after the first frame image is the second frame image, and the average value of the gradation values of the pixel group is the gradation value of the entire image. , the signal determination unit determines, based on the first video signal, that the gradation difference of the entire video, which is the difference between the gradation value of the entire video of the first frame and the gradation value of the entire video of the second frame, is a predetermined value. The signal converter determines whether or not the threshold is exceeded, and if the signal converter determines that the gradation difference of the entire video exceeds the threshold, the signal converter converts the first frame video and the second frame video. A second video signal is generated in which a new frame of video is inserted between them, and the gradation value of the entire new frame video is equal to the gradation value of the entire first frame video and the second frame video. It is between the overall gradation value.

This provides a display device that includes the display control device according to claim 1 or 2 and a display panel including a pixel group made of self-luminous elements, and in which electromagnetic radiation noise in the display panel is reduced.

Note that the reference numerals in parentheses attached to each component etc. indicate an example of the correspondence between the component etc. and specific components etc. described in the embodiments to be described later.

FIG. 1 is a block diagram showing an example of the configuration of a display device according to a first embodiment. FIG. 3 is a diagram showing a part of a pixel group made up of self-emitting elements, current, and radiation noise, and is a diagram illustrating an example of a situation where radiation noise occurs. 3 is a diagram for explaining that radiation noise is reduced by converting a video signal for a part of the pixel group shown in FIG. 2. FIG. 7 is a flowchart illustrating an example of radiation noise reduction processing in the display device of the first embodiment. FIG. 2 is a block diagram showing a configuration example of a display device according to a modification of the first embodiment. FIG. 7 is a diagram for explaining radiation noise reduction processing in a display device according to another modification of the first embodiment. FIG. 2 is a block diagram illustrating a configuration example of a display device according to a second embodiment. FIG. 7 is a diagram for explaining a gaze region in which radiation noise reduction processing is performed in a display device according to a second embodiment. 12 is a flowchart illustrating an example of radiation noise reduction processing in the display device of the second embodiment.

Embodiments of the present invention will be described below based on the drawings. Note that in each of the following embodiments, parts that are the same or equivalent to each other will be described with the same reference numerals.

(First embodiment)
〔composition〕
For example, as shown in FIG. 1, the display device 1 of this embodiment includes a display panel 2 having a pixel group made of self-luminous elements, and a display control unit 3 that controls image display on the display panel 2. Be prepared. The display device 1 receives a video signal from another electronic device (not shown), displays various videos on the display panel 2 based on the video signal, and when a predetermined condition is met, the display control unit 3 displays the video. The configuration is configured to perform conversion processing on at least a portion of a signal.

The display panel 2 is a display having a pixel group made up of self-luminous elements, and is, for example, an organic light emitting diode (OLED) panel. The display panel 2 displays various images based on video signals output from the display control section 3.

For example, an OLED panel is formed by laminating, in this order, a TFT layer including thin film transistors (TFTs) and an OLED layer including OLED elements constituting pixels on an arbitrary substrate. The TFT layer includes, for example, a gate electrode, a gate insulating layer, a semiconductor layer, a source electrode, and a drain electrode, and includes a plurality of TFT elements whose current can be turned on and off by adjusting the voltage of the gate electrode. The TFT element has, for example, a drain electrode connected to at least one of a pair of electrodes constituting the OLED element, and is used to drive and control the individual OLED elements. For example, an OLED layer is formed by sequentially stacking a hole injection layer, a hole transport layer, a light emitting layer, an electron transport layer, an electron injection layer, etc. on a TFT layer between a pair of electrodes, and emits light when a voltage is applied. It includes a plurality of OLED elements. For example, as shown in FIG. 2, an OLED panel has a plurality of pixels P each made of an OLED element, and the plurality of pixels P are arranged along one direction in plan view and an orthogonal direction perpendicular to the one direction. It is arranged repeatedly. The pixel P includes a plurality of sub-pixels (not shown) that emit different colors of emitted light, such as red, green, and blue, and may also be referred to as a "main pixel."

Note that the configurations and materials of OLEDs, TFTs, and OLED panels are well known, and therefore detailed description thereof will be omitted in this specification. Moreover, the OLED, TFT, and OLED panel are not limited to the above-described configuration, and any other configuration may be adopted.

The display control unit 3 is, for example, an electronic control unit in which a CPU, T-CON, ROM, RAM, etc. are mounted on a circuit board (not shown), and includes a driving IC such as an ASIC (Application Specific Integrated Circuit). It is. For example, when a video signal is input from another electronic device (not shown), the display control unit 3 generates a video signal based on the video signal and outputs it to the display panel 2 . Further, when the video signal satisfies a predetermined condition, the display control unit 3 converts at least a portion of the video signal and outputs the converted video signal to the display panel 2 in order to reduce radiation noise on the display panel 2. The display control section 3 has a configuration including, for example, a video processing circuit 31, a signal determination section 32, a signal conversion section 33, a storage section 34, and a video output section 35, as shown in FIG.

For example, the video processing circuit 31 receives a video signal from another electronic device (not shown), and uses a known video processing technique to respond to each luminescent color (for example, red, green, blue) constituting the display panel 2. Performs video processing to generate video signals. For example, in video processing, the video processing circuit 31 writes or reads a generated video signal into the storage unit 34 as data.

Hereinafter, for convenience of explanation, the video signal generated by the video processing circuit 31 will be referred to as a "first video signal."

In this embodiment, the signal determination unit 32 satisfies a predetermined condition between adjacent pixels (hereinafter simply referred to as "between adjacent pixels") among the pixel group that constitutes the display panel 2 based on the first video signal. Determine whether or not. In other words, the signal determination unit 32 determines whether or not the situation is such that radiation noise, which will be described later, may occur between adjacent pixels. For example, the signal determination unit 32 determines whether the difference in gradation values between adjacent pixels, that is, the gradation difference, exceeds a predetermined threshold based on the first video signal, and based on the determination result, The configuration is such that it outputs an electrical signal.
Note that the determination program executed by the signal determination section 32 and various data such as predetermined threshold values used in the program are stored in the storage section 34, for example. This predetermined threshold value can be changed as appropriate depending on conditions such as the level of radiation noise to be reduced, the type and resolution of the image displayed on the display panel 2, and the visual distance between the display panel 2 and the user.

When the signal determining unit 32 determines that the situation is such that radiation noise may occur between adjacent pixels, the signal converting unit 33 executes a process of converting at least a portion of the video signal. For example, when the signal determining unit 32 determines that the tone difference between adjacent pixels exceeds a predetermined threshold, the signal converting unit 33 converts a part of the first video signal used in the determination into the above-described predetermined A video signal (hereinafter referred to as "second video signal") that is converted so as to be less than the threshold value is generated.

Note that the generation of radiant noise in the video signal and the display panel 2, and the process of reducing the radiant noise of the display panel 2 by the signal determining section 32 and the signal converting section 33 will be described later.

The storage unit 34 is a storage medium including a nonvolatile memory such as a ROM and a volatile memory such as a RAM. The storage unit 34 stores various programs executed by the signal determining unit 32 and the signal converting unit 33 and various data such as threshold values used in these programs. Furthermore, the storage unit 34 temporarily stores the first video signal in one of the two adjacent pixels and the first video signal in the other pixel when the signal determination unit 32 makes a determination. Furthermore, the storage unit 34 stores the second video signal converted by the signal conversion unit 33 as necessary.

The video output section 35 outputs the video signal processed within the display control section 3 to the display panel 2, and based on the determination result of the signal determination section 32, it outputs the first video signal or the second video signal. is output to the display panel 2.

That is, in the present embodiment, the display control unit 3 uses the signal determination unit 32 and the signal conversion unit 33 to reduce radiation noise as necessary based on the first video signal generated by the video processing circuit 31. This constitutes a display control device that executes the processing.

The above is the basic configuration of the display device 1 of this embodiment.

[Reduction of radiated noise]
Next, an example in which radiant noise occurs in the display panel 2 and a process for reducing the radiant noise in the display panel 2 that is executed in the display device 1 in such an example will be described with reference to FIGS. 2 and 3. do.

In FIGS. 2 and 3, in order to show the rows and columns consisting of the pixel P groups of the display panel 2, which will be described later, for convenience, the pixel P groups along the left-right direction of the paper are shown as X1, X2, X3, and X4 in order from the left. A symbol is attached. Further, in FIGS. 2 and 3, groups of pixels P along a direction perpendicular to the arrangement direction of X1 to X4 are labeled Y1, Y2, Y3, and Y4 in order from the top. In addition, in FIGS. 2 and 3, the current and noise of the pixel P group of X1 and the current and noise of the pixel P group of Y3 are shown, and for easier viewing, the outline of a part of the pixel P group is shown with broken lines. ing.

In FIG. 2, those of the pixel P group with a high current value (gradation value) are shown in white, and the pixels of the pixel P group with a low current value (gradation value) are shown in black. In FIG. 3, although a cross section is not shown, pixels P having a gradation value approximately intermediate between the pixel P having a high gradation value and the pixel P having a low gradation value shown in FIG. 2 are hatched.

First, radiation noise generated in the display panel 2 will be explained with reference to FIG. 2.

For example, as shown in FIG. 2, some of the pixel groups P constituting the display panel 2 have high gradation values (for example, 100%, white display) and low gradation values (for example, 0%, black display). ) will be considered when a video signal is input in which the images are alternately arranged.

For the group of pixels P located in the X1 column, as shown in FIG. This results in a state where the value fluctuates greatly. Furthermore, in the pixel P group located in the row Y4, when the gradation values at X1 and X3 are high and the gradation values at X2 and X4 are low, the current value fluctuation between adjacent pixels is large. becomes. This is because, unlike a liquid crystal panel that has a common backlight source, the display panel 2 has a pixel P group made of self-luminous elements such as OLEDs, and each pixel P group is configured to emit light by individual current drive. It is.

When the display panel 2 is caused to emit light under the driving conditions described above, the pattern waveforms of the current in the X1 column and the current in the Y4 row will not be able to keep up with the current control due to the difference in current value between adjacent pixels, and the peak portion will fluctuate excessively. will occur. When this current peak portion occurs, radiation noise occurs in the X1 column and the Y3 row, as shown in FIG.

For example, the radiation noise reduction method described in Patent Document 1 described above can reduce radiation noise caused by high-speed transmission of electrical signals in the drive IC that outputs video signals to the display panel 2; It is difficult to deal with the radiation noise generated by

Therefore, the present inventors discovered that the cause of the radiation noise in the display panel 2 is the amount of current fluctuation between adjacent pixels, and by suppressing the fluctuation of the gradation value between adjacent pixels to a predetermined value or less, the radiation noise can be reduced. We presumed that this could be reduced, and thus created the display device 1 of this embodiment.

Specifically, in the display device 1, for example, in the case of a group of pixels P located in the column X1 shown in FIG. Then, these gradation values are stored in the storage section 34. Subsequently, the display control unit 3 calculates, for example, the difference between the gradation values of Y1 and Y2, and determines whether or not the difference between the gradation values exceeds a predetermined threshold value stored in advance in the storage unit 34. Perform the processing to do. Then, when the difference between the calculated gradation values exceeds a predetermined threshold, the display control unit 3 calculates an intermediate gradation value between the gradation value of Y1 and Y2, and calculates the gradation value between Y1 and Y2. The first video signal is converted so as to have the intermediate gradation value calculated for each. The display control unit 3 performs the same process as described above for the other two adjacent pixels P located at Y3 and Y4 in the X1 column, for example. Furthermore, the display control unit 3 sequentially repeats the above-described process for the other groups of pixels P located in the columns X2 and X3, using two adjacent pixels as one pair. Furthermore, the display control unit 3 performs similar processing on groups of pixels P in other areas (not shown).

As a result, the two pixels P located at Y1 and Y2 in the X1 column and the two pixels P located at Y3 and Y4 have the same gradation value, as shown in FIG. The gradation difference disappears. Similarly, the two pixels P located at X1 and X2 in the row Y3 and the two pixels P located at X3 and X4 have the same gradation value, and there is no difference in gradation between adjacent pixels. As a result, as shown in FIG. 3, for example, the pixels P of Y1 to Y4 located in the column X1 and the pixels P of X1 to The current of Y4 becomes constant. Therefore, the peak portion of excessive current fluctuation between adjacent pixels is eliminated, and the generation of radiation noise on the display panel 2 can be suppressed.

Note that in the above, two adjacent pixels P are treated as one pair, and current correction is performed when there is a difference in gradation value of a predetermined value or more, so the gradation value is corrected to a gradation value different from the original gradation value. There is a concern that the occurrence of pixels P may reduce the resolution of the video and reduce the visibility of the video. However, if the number of pixels P constituting the display panel 2 exceeds the resolution limit that can be recognized by the human eye, even if the resolution decreases, it will be difficult for the human eye to perceive, and the user will not feel uncomfortable. . In other words, depending on the number of pixels P on the display panel 2, the display device 1 performs the same process as described above using three or more adjacent pixels P as one pair to reduce radiation noise on the display panel 2. It may be a configuration.

Further, the limit of resolution that can be recognized by the human eye (hereinafter referred to as "resolution limit") is, for example, but not limited to, when the viewing distance of the display panel 2 from a user with visual acuity of 1.0 is 1.1 m. In some cases, it is about 300 ppi. The resolution limit of the display panel 2 varies depending on the user's visual acuity and viewing distance.

Further, when the gradation value of the adjacent pixel is less than a predetermined threshold value, the display control unit 3 outputs the first video signal as it is to the display panel 2. In this case, an original video based on the video signal input to the display control section 3 will be displayed on the display panel 2.

[Threshold value in radiated noise reduction processing]
From the perspective of achieving a balance between reducing radiation noise and suppressing image blur on the display panel 2, the predetermined threshold is preferably set within a range of 40% to 60%, for example, although it is not limited to this. , more preferably set to 50%.

For example, if the threshold value for the difference in gradation values between adjacent pixels is set to a small value such as 25% or less, even when display panel 2 displays an image that uses many halftones, such as a TV image, the radiation Noise reduction processing will be executed. In this case, radiation noise reduction processing will be performed on most of the pixel P groups used for displaying the image on the display panel 2, and as a result, the entire image will become blurred, and the visibility of the image will deteriorate. There are concerns.

On the other hand, if the threshold value for the difference in gradation values between adjacent pixels is set as high as, for example, 75% or more, the number of pixels P that performs the radiant noise reduction process will be too limited, and the radiant noise reduction effect will be reduced. It will fade.

On the other hand, if the predetermined threshold is set to, for example, 50% and the radiant noise reduction process is executed in a situation where the difference in gradation values of adjacent pixels exceeds 50%, the radiant noise reduction process is unnecessary. Execution is suppressed. In addition, by suppressing unnecessary radiant noise reduction processing, image blur caused by small gradation differences between adjacent pixels is suppressed, so a balance can be achieved between reducing radiant noise and suppressing image blur. becomes.

Note that "the gradation difference is 50%" here means that the gradation value (for example, 0) when the pixel P does not emit light is 0%, and the gradation value (for example, 0) when the pixel P is emitted at maximum brightness. 255) as 100%, it means that the difference in gradation values corresponds to 50%. For example, a case where one of the adjacent pixels has a gradation value of 25% and the other has a gradation value of 75% corresponds to a situation where the gradation difference is 50%.

[Example of processing operation]
Next, an example of a processing operation for reducing radiation noise in the display device 1 will be described with reference to FIG. 4.

The display device 1 executes the control flow shown in FIG. 4, for example, when the power is turned on.

In step S101, the video processing circuit 31 receives a video signal from an external electronic device (not shown), and generates a first video signal based on the video signal.

In the subsequent step S102, the display control unit 3 calculates the gradation value of the pixel P group constituting the display panel 2 based on the first video signal, and also calculates the gradation value between adjacent pixels P of the pixel P group. Calculate the difference in gradation values. After calculating the difference in gradation values between adjacent pixels, the display control unit 3 advances the process to step S103.

In step S103, the signal determination unit 32 determines, for example, whether the difference between the tone values calculated in step S102 exceeds a predetermined threshold stored in the storage unit 34. When the display control unit 3 makes an affirmative determination in step S103, the process proceeds to step S104, whereas in the case of a negative determination in step S103, the display control unit 3 skips step S104 and proceeds to step S105.

In step S104, the signal conversion unit 33 converts adjacent pixels whose gradation values exceed a predetermined threshold value to a first gradation value so that each of the adjacent pixels has a gradation value that is intermediate between these gradation values. The video signal is converted to generate a second video signal.

In step S105, the video output unit 35 outputs the first video signal or the second video signal to the display panel 2. Thereby, although various images are displayed on the display panel 2, the generation of radiation noise on the display panel 2 is suppressed.

According to this embodiment, when the gradation difference between adjacent pixels among the pixel group made up of self-luminous elements constituting the display panel 2 exceeds a predetermined threshold, the gradation values of the adjacent pixels are made equal. A display device 1 includes a display control section 3 that converts a video signal. Therefore, the gradation difference between adjacent pixels is suppressed from exceeding a predetermined value, and radiation noise on the display panel 2 caused by the gradation difference between adjacent pixels is reduced.

(Modification 1 of the first embodiment)
The display device 1 may control whether or not to perform the above-described radiation noise reduction process, depending on the content of the video displayed on the display panel 2. For example, when the display panel 2 displays important information (hereinafter referred to as "important display") that is highly important information in part or in whole, the area where the important display is displayed is determined from the perspective of ensuring visibility. , the configuration may be such that the radiation noise reduction process is not performed.

For example, in the case of in-vehicle applications, important displays include, but are not limited to, text information about the vehicle such as speed and rotational speed, images from outside the vehicle from an in-vehicle camera, and display on the navigation screen of a navigation device. On the other hand, displays that do not fall under the category of important displays (hereinafter referred to as "normal displays") include, but are not limited to, in-vehicle applications, such as entertainment content such as viewing videos such as DVDs and TVs, and audio equipment. Examples include display content.

Hereinafter, to simplify the explanation, the area of the display panel 2 where important displays are displayed will be referred to as the "important display area", and the remaining part of the display panel 2, that is, the area where normal displays will be displayed, will be referred to as the "normal display area". Sometimes.

In this case, the display device 1 further includes a content classification unit 36 in the display control unit 3, as shown in FIG. The configuration is such that The content classification unit 36 classifies the information into important information and other information using, for example, a known video recognition technique. In other words, the content classification unit 36 plays a role of extracting important information from the video displayed on the display panel 2.

The video output unit 35 outputs the first video signal to the important display area of the display panel 2, and outputs the first video signal or the first video signal to the normal display area of the display panel 2 where a display different from the important display is displayed. 2 video signal is output. In other words, the display device 1 according to the present modification is configured to selectively perform radiation noise reduction processing on the normal display area of the display panel 2 to ensure visibility of the important display area.

According to this modification, it is possible to perform radiation noise reduction processing on the normal display area where other information is displayed while ensuring the visibility of the portion of the display panel 2 that displays important information.

In addition, in order to ensure the visibility of the important display, the display device 1 according to this modification also includes a portion of the normal display located within a predetermined range centered on the important display (hereinafter referred to as "adjacent area"). , as in the important display section, the radiation noise reduction process may not be performed.

Further, in this case, when the important display area is located at the center of the display panel 2 and the adjacent area of the normal display area is not subjected to radiation noise reduction processing, the area of the adjacent area may be changed as appropriate. For example, the area of the adjacent region may be changed depending on predetermined conditions such as the frame rate of the video, the brightness of the environment around the display panel 2, the visual acuity of the users, and the number of users.

Specifically, in situations where changes in video brightness due to radiation noise reduction processing are likely to be noticeable, such as when the frame rate is slow, the surrounding environment is dark, the user has good eyesight, or there are multiple users, adjacent areas may It is set large. On the other hand, in situations where changes in image brightness due to radiation noise reduction processing are less noticeable, such as when the frame rate is fast, the surrounding environment is bright, the user has poor eyesight, or there is only one user, the adjacent area is set small. .

Note that, for example, if the area of the adjacent region is set large, 70% or more of the display surface of the display panel 2 will be affected by radiation noise, and if the area of the adjacent region is set small, less than half of the display surface will be affected by radiation noise. However, the present invention is not limited to this example.

Furthermore, in the case of in-vehicle applications, a situation where changes in image brightness are more noticeable is when the vehicle speed is slow. On the other hand, a situation where the change in brightness of the image is less noticeable is when the vehicle speed is high. This is because the faster the vehicle speed is, the narrower the driver's field of view becomes, and the slower the vehicle speed is, the wider the driver's field of view becomes. In particular, when the display panel 2 has a translucent structure and is placed overlapping a transparent member such as a windshield, setting the adjacent area according to the vehicle speed is effective.

Note that the frame rate is obtained, for example, from the video signal, and whether it is "fast" or "slow" can be determined based on whether it is 30 fps or more. The brightness of the surrounding environment can be obtained by, for example, an arbitrary illuminance sensor, and whether it is "bright" or "dark" can be determined based on whether it is 1000 lm/m ² or more. The user's visual acuity is obtained, for example, by numerical input by the user, and whether it is "good" or "bad" can be determined by whether it is 1.0 or more, but considering the human resolution limit, the display panel The threshold value may vary depending on the visual recognition distance from 2. The number of users is obtained, for example, in the case of vehicle-mounted applications, by an arbitrary sensor provided on the seat, such as a seat belt sensor.

Further, the vehicle speed is obtained, for example, by a speed sensor or a vehicle speed pulse used in a known car navigation device, and whether the vehicle is "fast" or "slow" can be determined based on whether the speed is 40 km/h or more.

Furthermore, in the above-mentioned control of adjacent areas, an example was explained in which one threshold value was set for each of various conditions such as the video frame rate, but the invention is not limited to this, and multiple threshold values and data tables may be set up. It may be executed manually.

For example, in the case of vehicle speed, stepwise thresholds may be set depending on the characteristics of the viewing angle of a person depending on the speed. A person's effective viewing angle with respect to vehicle speed varies, for example, 100° at 40 km/h, 65° at 70 km/h, and 40° at 100 km/h. In this case, if a change in brightness of the video occurs within the range of the person's effective viewing angle depending on the speed, the change in brightness will be recognized by the person, and will have a large effect on the visibility of important displays in the video. Therefore, the adjacent area may be set stepwise or continuously according to the vehicle speed as the outline of the effective viewing angle of the person at the vehicle speed. In other words, the range of the display panel 2 in which the radiation noise reduction process is performed is set to a range where the visibility of important displays is less affected, that is, outside the range of the effective viewing angle of a person at a vehicle speed.

(Modification 2 of the first embodiment)
The display device 1 may reduce the radiation noise when the variation in the gradation value of the entire image displayed on the display panel 2 exceeds a predetermined value, rather than the gradation difference between adjacent pixels.

Hereinafter, for convenience of explanation, an image displayed on the display panel 2 at a certain moment, as shown in FIG. 6, for example, will be referred to as a "first frame image." Furthermore, when the first video signal is not converted, the video displayed on the display panel 2 at the moment after the first frame is referred to as "second frame video."

Although FIG. 6 does not show a cross section, the first frame image and the inserted frame are hatched as indicators of the brightness of the first frame image, the second frame image, and the inserted frame image described later. ing. Further, in FIG. 6, the flow of time is shown by arrows in order to make it easier to understand the display order of video of each frame. Note that the gradation values of the entire video shown in FIG. 6 are smaller in the order of the second frame video, the inserted frame video, and the first frame video.

In this modification, the signal determination unit 32 determines, for example, the gradation value of the entire video of the first frame (hereinafter referred to as "first gradation value") and the video of the second frame, based on the first video signal. The entire gradation value (hereinafter referred to as "second gradation value") is calculated. Then, the signal determination unit 32 determines whether the difference between the first gradation value and the second gradation value exceeds a predetermined value. The predetermined value (threshold value) used for this determination may be changed as appropriate.

The signal conversion unit 33 converts the first video signal into a second video signal when the signal determination unit 32 determines that the difference between the first gradation value and the second gradation value exceeds a predetermined value. Convert to signal. In this case, the signal converter 33 converts the first video so that a new frame of video is inserted between the consecutive first and second frames of video, as shown in FIG. Performs signal conversion processing.

The gradation value of the video of the new frame to be inserted, that is, the entire video of the inserted frame, is set, for example, to be intermediate between the first gradation value and the second gradation value. In other words, in this modification, when the signal determining unit 32 determines that the gradation difference of the entire video of the previous and subsequent frames exceeds a predetermined value, the signal converting unit 33 converts the gradation value from the video of the previous and subsequent frames. plays the role of generating and interpolating intermediate frames.

As a result, these halftone insertion frames are added between the first frame video and the second frame video, reducing the amount of variation in power consumption when switching from the first frame to the second frame. It will be done. Therefore, the radiation noise on the display panel 2 caused by the amount of variation in power consumption when switching images is reduced.

Note that the radiation noise reduction process according to this modification is preferably performed when the number of pixels P of the display panel 2 is at a low resolution level. For example, in the case of a low-resolution display panel 2, the number of pixels for displaying images is small, so when the same radiant noise reduction process as in the first embodiment is performed, the brightness change due to the process is not visible to the user. image visibility may deteriorate. On the other hand, in the above-mentioned radiation noise reduction processing (hereinafter simply referred to as "frame control") in which inserted frames are interpolated between consecutive frames, the gradation value of the entire video changes for each frame. Therefore, this frame control can be applied even if the display panel 2 has a low resolution, since it is difficult for the user to visually recognize a change in the brightness of the image due to the frame control, and it is difficult for the user to feel uncomfortable with the image.

Furthermore, the display panel 2 having a "low resolution" as used herein means that the pixel P group constituting the display panel 2 is below the resolution limit. On the other hand, if the group of pixels P constituting the display panel 2 exceeds the resolution limit, it can be said that the display panel 2 has a "high resolution".

According to this modification, the amount of change in power consumption between frames is reduced by interpolating an insertion frame that is the halftone of the video in these frames between the first and second consecutive frames. be done. Therefore, it is possible to reduce the radiation noise in the display panel 2 caused by the magnitude of the amount of change in power consumption between frames.

In addition, in the above example, the gradation value of the entire video of the inserted frame interpolated between the consecutive first frame and the second frame is the gradation value of the entire video of the first frame and the gradation value of the entire video of the second frame. Although an example has been described in which the gradation value is set midway between the gradation value and the gradation value of , this may be executed pixel by pixel. That is, each pixel group of the display panel 2 interpolates an inserted frame in which the gradation value is intermediate between the gradation value in the first frame video and the gradation value in the second frame video, pixel by pixel. Good too.

Furthermore, in the method of reducing radiant noise using frame control in this modification, it is not necessary to perform a determination process using a threshold value when adjusting tone values. This reduces the number of steps in the radiation noise reduction process, and is also expected to have the effect of reducing the processing load on the display control unit 3. Note that in this case, the display control section 3 is configured without the signal determination section 32.

(Second embodiment)
The display device 1 of the second embodiment will be explained with reference to FIGS. 7 to 9. The display device 1 of this embodiment is preferably mounted on a moving body such as a car and used as an in-vehicle display device used by a user such as a driver of the moving body. In this embodiment, a case where the display device is mounted on a vehicle will be described as a representative example, but the present invention is not limited to this use and may be applied to other uses as well.

In FIG. 8, the imaging range by the line-of-sight detection unit 4, which will be described later, is indicated by a broken line, and the direction of the user's line-of-sight is indicated by an arrow.

As shown in FIG. 7, for example, the display device 1 of this embodiment includes a line-of-sight detection unit 4 that detects the line-of-sight of a predetermined user, and calculates an area of the display panel 2 that the user gazes at based on the detected line-of-sight. This embodiment differs from the first embodiment in that it includes a gaze area calculation unit 37 that performs the following. In this embodiment, this difference will be mainly explained.

The line of sight detection unit 4 detects the line of sight of the user by capturing an image of a predetermined area where the eyes of the user viewing the display panel 2 are assumed to exist, and analyzing the image including the eyeballs of the occupant. For example, in the case of in-vehicle use, the line-of-sight detection unit 4 captures an image of a user such as a driver of a vehicle (moving object) in which the display device 1 is mounted, and detects the line-of-sight. The line-of-sight detection unit 4 is, for example, separate from the display panel 2, and its arrangement can be changed as appropriate depending on the user to be imaged. For example, based on a known image recognition technology, the line of sight detection unit 4 detects the outline of the user's face, various parts such as eyes, nose, mouth, etc. based on the captured face image of the user, and also detects the positions of the various parts. It is designed to analyze relationships and eye positions. As the line of sight detection section 4, for example, in the case of in-vehicle use, a driver status monitor manufactured by Denso Corporation, which has a near-infrared camera, ECU (abbreviation for electronic control unit), etc. (not shown), may be used. , but not limited to.

The line of sight detection unit 4 detects, for example, the position of the reflected image of the light emitting element of the near-infrared camera reflected in the eyeball and the position of the pupil by image analysis, and calculates the direction of the line of sight based on these relative positions. The configuration is such that This is because when the direction of the passenger's line of sight to be imaged changes, the position of the part of the line of sight detection unit 4 reflected in the imaged eyeball (such as the light emitting element of a near-infrared camera) does not change almost; This takes advantage of the fact that the position of The line-of-sight detection unit 4 can detect the direction of the line-of-sight of the user to be imaged, for example, using the above-mentioned well-known line-of-sight detection technique. The line of sight detection section 4 is connected to the display control section 3 and an external power source (not shown). The user's line-of-sight information obtained by the line-of-sight detection unit 4 is transmitted to the display control unit 3 and used to determine the area of the display panel 2 where the radiation noise reduction process is performed.

For example, as shown in FIG. 8, the gaze area calculation unit 37 calculates a gaze area, which is an area of the video display surface 2a of the display panel 2 that is gazed by the user, based on the user's gaze information acquired from the gaze detection unit 4. Calculate 2aa. For example, the position coordinates of the display panel 2 are stored in the storage unit 34 in advance, and the gaze area calculation unit 37 calculates the position coordinates of the display panel 2 based on the position coordinates, the position coordinates of the user's eyes, and the direction of the line of sight obtained from the line of sight detection unit 4. , a gaze point 21, which is the intersection of the user's line of sight and the video display surface 2a, is calculated. Then, the gaze area calculation unit 37 calculates, for example, a predetermined area around the calculated gaze point 21 as the gaze area 2aa, and the remaining part of the display panel 2 that is different from the gaze area 2aa as the peripheral area 2ab. calculate.

Note that the predetermined range for calculating the gaze area 2aa is, for example, a range assuming a person's effective visual field (within a viewing angle of 20 degrees) centered on the gaze point 21. Data regarding this predetermined range is stored in advance in the storage unit 34, for example. In addition, during this calculation, the gaze area calculation unit 37 acquires information on the distance between the display panel 2 and the user's eyes, that is, the viewing distance, from the line of sight detection unit 4, and stores the information, the gaze point 21, and the storage unit 34. The gaze area 2aa is calculated based on the predetermined range stored in .

Next, an example of the processing operation in the radiation noise reduction process in the display device 1 of this embodiment will be described with reference to FIG. 9. Note that since there are many parts in common with the radiation noise reduction process in the display device 1 of the first embodiment, here, parts that are different from the first embodiment will be mainly described.

For example, as shown in FIG. 9, the display device 1 of this embodiment performs the same processing as in the first embodiment in receiving the video signal in step S101 and calculating the tone difference between adjacent pixels in step S102. It will be done. In the subsequent step S103, if it is determined that the gradation difference between adjacent pixels exceeds a predetermined threshold, that is, in the case of an affirmative determination, the display control unit 3 advances the process to step S201. On the other hand, in the case of a negative determination in step S103, the display control unit 3 advances the process to step S105.

In step S<b>201 , the line-of-sight detection unit 4 images the user's eyes, calculates the user's line-of-sight using a known image authentication technique, and transmits the calculated line-of-sight information to the display control unit 3 . Then, the gaze area calculation unit 37 that has acquired the line-of-sight information calculates the gaze area 2aa on the video display surface 2a of the display panel 2. After completing step S201, the display control unit 3 advances the process to step S202.

In step S202, for example, the display control unit 3 determines whether the portion where the gradation difference is determined to exceed a predetermined threshold is within the gaze area 2aa. When the display control unit 3 makes an affirmative determination in step S202, the process proceeds to step S105, and in the case of a negative determination in step S202, the process proceeds to step S104.

In step S104, for example, the signal converter 33 converts the first video signal into a second video signal. After that, the display control unit 3 advances the process to step S105.

In step S105, the video output unit 35 outputs the first video signal for the gaze area 2aa, and outputs the first video signal or the second video signal for the peripheral area 2ab.

As a result of the above processing operations, the radiant noise reduction process is not performed in the gaze area 2aa where the user gazes, and the radiant noise reduction process is performed as necessary in the peripheral area 2ab where the user is less likely to feel discomfort.

Note that the above processing operation is an example, and the order of processing may be changed within a possible range. For example, the calculation of the gaze area 2aa in step S201 is not limited to after step S103, but may be performed before step S103, or may be performed in parallel with step S101 or step S102.

According to the present embodiment, the display device 1 selectively performs radiation noise reduction processing on a peripheral region 2ab different from the gaze region 2aa that the user gazes at. In other words, the configuration is such that, while ensuring visibility in the gaze area 2aa where the user gazes, the radiant noise reduction process is executed in a peripheral area 2ab where the user is less likely to feel discomfort even if the brightness of the image changes. Therefore, the display device 1 can both ensure the visibility of images and reduce the radiation noise on the display panel 2.

(Other embodiments)
Although the present invention has been described based on examples, it is understood that the present invention is not limited to the examples or structures. The present invention also includes various modifications and equivalent modifications. In addition, various combinations and configurations, as well as other combinations and configurations that include only one, more, or less of these elements, fall within the scope and spirit of the present invention.

(1) For example, in each of the above embodiments, an example in which the display panel 2 is an OLED panel has been described, but the pixel P may be composed of a self-luminous element, and is not limited to an OLED panel. do not have. Examples of self-luminous elements other than OLEDs include inorganic EL (electroluminescence) and micro LEDs. In other words, the display panel 2 only needs to have a structure in which the pixel P groups are individually energized and emit light. For example, the display panel 2 may be an inorganic EL panel or a micro LED panel, or may include pixels P made of other known self-luminous elements. It may be prepared.

(2) In each of the above embodiments, the signal determination unit 32 and signal conversion unit 33 that function as a display control device that performs radiation noise reduction processing of the display panel 2 are part of the display control unit 3 that is separate from the display panel 2. Although an example has been described in which the unit is configured as a unit, the present invention is not limited thereto. For example, the signal determination section 32 and the signal conversion section 33 may be mounted on the display panel 2. In this case, the display control unit 3 generates a first video signal based on an external video signal and outputs it to the display panel 2. The display panel 2 uses a signal determination section 32 and a signal conversion section 33 mounted thereon to determine whether or not a predetermined condition is satisfied based on the first video signal, and to determine whether or not a predetermined condition is satisfied based on the first video signal, and to The configuration is such that a process of converting a first video signal into a second video signal is performed. In this case, the various programs executed in the signal determining section 32 and the signal converting section 33 and the various data used therein are stored, for example, in a storage medium (not shown) mounted on the display panel 2.

(3) In the first embodiment, in the radiation noise reduction process, if the gradation difference between a plurality of adjacent pixels P is equal to or greater than a predetermined value, each of the plurality of pixels P has an intermediate gradation value. An example of adjustment to a gradation value, that is, an intermediate gradation value has been described. However, the display device 1 may have any configuration as long as it can reduce radiation noise caused by a difference in gradation between adjacent pixels, and is not limited to an example in which each of the adjacent pixels has an intermediate gradation value.

For example, if the tone value of one of two adjacent pixels P is 0% and the tone value of the other is 100%, the tone value of that one pixel P is adjusted to 25%, and the tone value of the other pixel P is adjusted to 25%. The gradation value of P may be adjusted to 75%. In other words, the gradation difference between adjacent pixels P after the gradation value adjustment only needs to be equal to or less than a predetermined threshold, and the gradation values of the adjacent pixels after the gradation value adjustment do not have to be the same. Even in this case, the gradation difference between two adjacent pixels P forming a pair is, for example, 50% or less, and the gradation difference between adjacent pixels is reduced compared to before adjusting the gradation value, so the radiation Noise is suppressed.

Further, in this case, compared to when adjusting to an intermediate gradation value, the degree of reduction of radiation noise is reduced, and the degree of occurrence of image blur is also reduced. Therefore, even if the number of pixels P constituting the display panel 2 is below the human resolution limit, that is, in the case of low resolution, the deterioration in image visibility due to the above processing is suppressed, radiation noise is suppressed, and It is possible to maintain the visibility of images at the same time.

In this case, in step S104 of the control flow shown in FIG. 4, the signal conversion unit 33 determines that each of the adjacent pixels is within a predetermined range from the intermediate gradation value, and the gradation difference between these is, for example, 50% or less. The configuration is such that the first video signal is converted and the second video signal is generated.

2 Display panel 31 Video processing circuit 32 Signal determination unit 33 Signal conversion unit 35 Video output unit 36 Content classification unit 37 Gaze area calculation unit 4 Line of sight detection unit

Claims (6)

A display control device that suppresses electromagnetic radiation noise caused by differences in gradation values between adjacent main pixels among a group of main pixels formed by self-luminous elements constituting a display panel (2), comprising:
a video processing circuit (31) that generates a first video signal input to the display panel;
a signal determination unit (32) that determines, based on the first video signal, whether a difference in gradation value between the adjacent main pixels satisfies a predetermined condition;
Based on the determination result of the signal determination section, at least a portion of the first video signal is converted so that the difference in gradation values between the adjacent main pixels is less than a predetermined value, and a second video signal is converted. a signal converter (33) that generates a signal;
a video output unit (35) that outputs the first video signal or the second video signal to the display panel ,
The main pixel is composed of a plurality of sub-pixels that emit light of different colors,
The signal determination unit determines a tone difference, which is a difference between one tone value and the other tone value of adjacent main pixels of the group of main pixels, based on the first video signal. Determine whether or not exceeds a predetermined threshold;
The signal converting unit is configured to control, when the signal determining unit determines that the gradation difference exceeds a predetermined threshold, at least the gradation difference of the first video signal exceeds the threshold. A display control device that converts a portion of the adjacent main pixel and generates the second video signal . A display control device that suppresses electromagnetic radiation noise caused by differences in gradation values between consecutive video frames of a pixel group consisting of a main pixel formed by a self-emitting element constituting a display panel (2), comprising:
a video processing circuit (31) that generates a first video signal input to the display panel;
a signal determination unit (32) that determines whether the difference in the gradation values satisfies a predetermined condition based on the first video signal;
Signal conversion that converts at least a portion of the first video signal based on the determination result of the signal determination unit so that the difference in the gradation value is less than a predetermined value, and generates a second video signal. Part (33) and
a video output unit (35) that outputs the first video signal or the second video signal to the display panel,
The main pixel is composed of a plurality of sub-pixels that emit light of different colors,
An image displayed on the display panel at a certain moment is defined as a first frame image, an image displayed on the display panel at a moment after the first frame image is defined as a second frame image, and the image of the pixel group is defined as a second frame image. The average value of the gradation values is taken as the gradation value of the entire image,
The signal determination unit determines a gradation difference of the entire video, which is a difference between a gradation value of the entire video of the first frame and a gradation value of the entire video of the second frame, based on the first video signal. Determine whether or not exceeds a predetermined threshold;
The signal converter is configured to generate a new signal between the first frame image and the second frame image when the signal converter determines that the tone difference of the entire video exceeds the threshold. generating the second video signal into which a frame of video is inserted;
In the display control device, the gradation value of the entire video of the new frame is intermediate between the gradation value of the entire video of the first frame and the gradation value of the entire video of the second frame. a display panel (2) comprising a pixel group consisting of a main pixel made of a self-luminous element;
a video processing circuit (31) that generates a first video signal input to the display panel;
a signal determination unit (32) that determines whether a difference in gradation values between adjacent main pixels satisfies a predetermined condition based on the first video signal;
Based on the determination result of the signal determination section, at least a portion of the first video signal is converted so that the difference in gradation values between the adjacent main pixels is less than a predetermined value, and a second video signal is converted. a signal converter (33) that generates a signal;
a video output unit (35) that outputs the first video signal or the second video signal to the display panel ,
The main pixel is composed of a plurality of sub-pixels that emit light of different colors,
The signal determination unit determines a gradation level that is a difference between a gradation value of one gradation value and another gradation value of adjacent main pixels that are mutually adjacent main pixels among the pixel group, based on the first video signal. determining whether the difference exceeds a predetermined threshold;
The signal converting unit is configured to convert the first video signal into at least one of the adjacent video signals whose gradation difference exceeds the threshold when the signal determining unit determines that the gradation difference exceeds the threshold. A display device that converts a main pixel portion and generates the second video signal . a display panel (2) comprising a pixel group consisting of a main pixel made of a self-luminous element;
a video processing circuit (31) that generates a first video signal input to the display panel;
a signal determination unit (32) that determines, based on the first video signal, whether a difference in gradation value between frames of consecutive video images of the pixel group satisfies a predetermined condition;
Signal conversion that converts at least a portion of the first video signal based on the determination result of the signal determination unit so that the difference in the gradation value is less than a predetermined value, and generates a second video signal. Part (33) and
a video output unit (35) that outputs the first video signal or the second video signal to the display panel,
The main pixel is composed of a plurality of sub-pixels that emit light of different colors,
An image displayed on the display panel at a certain moment is defined as a first frame image, an image displayed on the display panel at the next instant after the first frame image is defined as a second frame image, and the image of the pixel group is defined as a second frame image. The average value of the gradation values is taken as the gradation value of the entire image,
The signal determination unit determines a gradation difference of the entire video, which is a difference between a gradation value of the entire video of the first frame and a gradation value of the entire video of the second frame, based on the first video signal. Determine whether or not exceeds a predetermined threshold;
The signal converter is configured to generate a new signal between the first frame image and the second frame image when the signal converter determines that the tone difference of the entire video exceeds the threshold. generating the second video signal into which a frame of video is inserted;
In the display device, the gradation value of the entire video of the new frame is intermediate between the gradation value of the entire video of the first frame and the gradation value of the entire video of the second frame. a line of sight detection unit (4) that images the eyes of a user viewing the display panel and detects the line of sight of the user;
further comprising a gaze area calculation unit (37) that calculates a gaze area (2aa) of the display panel that the user gazes at based on the line of sight;
The video output unit outputs the first video signal to the attention area of the display panel, and outputs the first video signal or the like to an area (2ab) of the display panel different from the attention area. The display device according to claim 3 , which outputs the second video signal. further comprising a content classification unit (36) that extracts the important information by treating information with a high degree of importance among the information displayed on the display panel as important information;
An area of the display panel where the important information is displayed is set as an important display area, and the video output unit outputs the first video signal to the important display area, and outputs the first video signal to the important display area of the display panel. 4. The display device according to claim 3 , wherein the first video signal or the second video signal is output to a different area.

Images