The present technology relates to a signal processing apparatus, a signal processing method, and a display apparatus, and in particular, to a signal processing apparatus, a signal processing method, and a display apparatus that allow moving image blur to be more appropriately removed.
In recent years, liquid crystal displays (LCD) and organic EL displays (Organic Electro Luminescence Displays), which prevail as display devices for video apparatuses, are hold-type display apparatuses. There have been reports that display apparatuses of these types are subject to moving image blur due to human visual properties.
Various suggestions have been made as methods for removing moving image blur. For example, an OLED display apparatus has been suggested that mitigates moving image blur by switching a mode depending on a content to perform driving with a pixel off period (hereinafter referred to as impulse driving) within one frame when a video content is reproduced (see, for example, PTL 1).
However, the video content includes various videos such as fast moving videos and videos close to still images, and thus the driving method disclosed in PTL 1 involves performing the impulse driving on videos prevented from suffering moving image blur, and is thus insufficient as removal of moving image blur.
The present technology has been contrived in view of such circumstances, and an object of the present technology is to more appropriately remove moving image blur.
A signal processing apparatus according to an aspect of the present technology is a signal processing apparatus including a detection section detecting a moving image blur video including a video in which moving image blur is easily visible, from videos included in a video content on a basis of a feature amount of the video content.
A signal processing method according to an aspect of the present technology is a signal processing method for a signal processing apparatus, in which the signal processing apparatus includes a detection section detecting a moving image blur video including a video in which moving image blur is easily visible, from videos included in a video content on a basis of a feature amount of the video content.
In the signal processing apparatus and the signal processing method according to the aspect of the present technology, the moving image blur video corresponding to the video in which the moving image blur is easily visible is detected from the videos included in the video content on the basis of the feature amount of the video content.
A display apparatus according to an aspect of the present technology is a display apparatus including a display section displaying videos of a video content, a detection section detecting a moving image blur video including a video in which moving image blur is easily visible, from videos included in a video content on a basis of a feature amount of the video content, and a control section controlling driving of the display section on a basis of a detection result for the moving image blur video detected.
In the display apparatus according to the aspect of the present invention, the videos of the video content are displayed, the moving image blur video corresponding to the video in which moving image blur is easily visible is detected from the videos included in the video content on the basis of the feature amount of the video content, and driving of the display section is controlled on the basis of the detection result for the moving image blur video detected.
The signal processing apparatus or the display apparatus according to the aspect of the present technology may be an independent apparatus or an internal block included in one apparatus.
According to the aspect of the present technology, moving image blur can be more appropriately removed.
Note that the effect described here is not necessarily limited and may be any of the effects described in the present disclosure.
Embodiments of the present technology will be described below with reference to the drawings. Note that description will be given in the following order.
Configuration of Liquid Crystal Display Apparatus
In
The signal processing section 11 executes predetermined video processing on the basis of a video signal input to the signal processing section 11. In the video signal processing, a video signal for controlling driving of the liquid crystal display section 13 is generated and fed to the display driving section 12. Additionally, in the video signal processing, a driving control signal (BL driving control signal) for controlling driving of the backlight 15 is generated and fed to the backlight driving section 14.
The display driving section 12 drives the liquid crystal display section 13 on the basis of the video signal fed from the signal processing section 11. The liquid crystal display section 13 is a display panel including pixels two-dimensionally arranged and each including a liquid crystal element and TFT (Thin Film Transistor) element. The liquid crystal display section 13 provides display by modulating light emitted from the backlight 15 in accordance with driving from the display driving section 12.
Here, the liquid crystal display section 13 includes, for example, two transparent substrates formed of glass or the like and between which a liquid crystal material is sealed. A portion of each of the transparent substrates that faces the liquid crystal material is provided with a transparent electrode formed of, for example, ITO (Indium Tin Oxide), and the transparent electrode forms a pixel along with the liquid crystal material. Note that, in the liquid crystal display section 13, each pixel includes, for example, three subpixels in red (R), green (G), and blue (B).
The backlight driving section 14 drives the backlight 15 on the basis of the driving control signal (BL driving control signal) fed from the signal processing section 11. The backlight 15 emits light generated by a plurality of light emitting elements, to the liquid crystal display section 13 in accordance with driving from the backlight driving section 14. Note that, for example, LEDs (light Emitting Diodes) can be used as the light emitting elements.
Configuration of Self-Luminous Display Apparatus
In
The signal processing section 21 executes predetermined video signal processing on the basis of a video signal input to the signal processing section 21. In the video signal processing, a video signal for controlling driving of the self-luminous display section 23 is generated and fed to the display driving section 22.
The display driving section 22 drives the self-luminous display section 23 on the basis of the video signal fed from the signal processing section 21. The self-luminous display section 23 is a display panel including pixels two-dimensionally arranged and each including a self-luminous element. The self-luminous display section 23 provides display in accordance with driving from the display driving section 22.
Here, the self-luminous display section 23 is, for example, a self-luminous display panel such as an organic EL display section (OLED display section) using organic electroluminescence (organic EL). Specifically, in a case where an organic EL display section (OLED display section) is adopted as the self-luminous display section 23, the self-luminous display apparatus 20 corresponds to an organic EL display apparatus (OLED display apparatus).
An OLED (Organic Light Emitting Diode) is a light emitting element including an organic light emitting material between a negative electrode and a positive electrode, and OLEDs form pixels two-dimensionally arranged in the organic EL display section (OLED display section). The OLED included in the pixel is driven in accordance with a driving control signal (OLED driving control signal) generated by video signal processing. Note that, in the self-luminous display section 23, each pixel includes, for example, four subpixels in red (R), green (G), blue (B), and white (W).
Incidentally, the above-described liquid crystal display apparatus 10 (
In contrast, in the liquid crystal display apparatus 10, by providing a period when the backlight 15 is off during one frame to cause pseudo impulse driving, moving image blur can be removed. On the other hand, in the self-luminous display apparatus 20, by providing a pixel off period during one frame to cause pseudo impulse driving, moving image blur can be removed.
Such an improvement method is disclosed in, for example, NPL 1 below.
However, this improvement method reduces luminance to degrade image quality due to the provision of the off period. In contrast, degradation of image quality can be suppressed by increasing a current supplied to the backlight 15 for the liquid crystal display section 13 and to the self-luminous elements included in the self-luminous display section 23, but power consumption or temperature may be increased or shortening of device life may be fostered.
Note that, as described above, the OLED display apparatus disclosed in PTL 1 switches a mode depending on a content to perform impulse driving with a pixel off period during one frame when a video content is reproduced.
However, the video content includes various videos such as fast moving videos and videos close to still images, and thus the above-described driving method involves performing the impulse driving on videos in which no moving image blur occurs, and is thus insufficient as removal of moving image blur.
Thus, the present technology causes the impulse driving to be performed when moving image blur is easily visible, allowing moving image blur to be more appropriately removed.
In
Here, moving image blur may occur while an object in the video is moving. Accordingly, in a scene like a video 501 in which cars are traveling, moving image blur is easily visible, and thus instead of normal driving based on a driving method in A of
Specifically, in the driving method in A of
By switching from the driving method in A of
In other words, in the present technology, in a scene like the video 501 in which moving image blur is easily visible, what is called impulse-type driving with brightness maintained (impulse driving) is performed to remove moving image blur, thus allowing provision of optimal image quality compatible with a displayed video.
Note that
However, in the self-luminous display apparatus 20, during execution of the normal driving based on the driving method in A of
Configuration of Signal Processing Section
In
The moving image blur video detecting section 101 detects a video in which moving image blur is easily visible (hereinafter referred to as a moving image blur video) from videos included in a video content on the basis of a video signal for the video content input to the moving image blur video detecting section 101, and feeds a detection result to the on period calculating section 102.
The moving image blur video detecting section 101 includes a video information acquiring section 111, a luminance information acquiring section 112, and a resolution information acquiring section 113.
The video information acquiring section 111 executes video information acquiring processing on the video signal for the video content, and feeds a corresponding processing result to the on period calculating section 102 as video information.
Here, moving image blur do not occur unless an object displayed as a video moves, and thus, in video information acquisition processing, a moving image amount is detected as an indicator representing movement of the object in the video.
For a detection method for the moving image amount, detection can be achieved using a difference in luminance of each pixel between video frames or a moving vector amount of each pixel or the object. Furthermore, the moving image amount may be detected using detection of captions in which moving image blur is typically easily visible or detection of pan (panning) of a camera.
The luminance information acquiring section 112 executes luminance information acquisition processing on a video signal for a video content, and feeds a corresponding processing result to the on period calculating section 102 as luminance information.
Here, for example, in a case where driving is performed on a video with a peak luminance focused on, it is sometimes better that switching to the impulse driving is avoided, and in this luminance information acquisition processing, luminance information such as peak luminance information can be detected. Note that details of an example of driving with the peak luminance information taken into account will be described below with reference to
The resolution information acquiring section 113 executes resolution information acquisition processing on the video signal for the video content, and feeds a corresponding processing result to the on period calculating section 102 as resolution information.
Here, moving image blur occur at edge portions of the video and not at flat portions, and thus, for example, in the resolution information acquisition processing, the spatial resolution of the video is analyzed to detect an edge amount as an indicator representing edge portions included in the video.
For a detection method for the edge amount (edge portions), for example, detection can be achieved by, for example, a method of using a plurality of bandpass filters that pass only specific frequencies.
Note that the video information, luminance information, and resolution information detected by the moving image blur video detecting section 101 are feature amounts of the video content (feature amounts obtained from the video content) and that a moving image blur video is detected on the basis of the feature amounts. Additionally,
The on period calculating section 102 is fed with the video information from the video information acquiring section 111, the luminance information from the luminance information acquiring section 112, and the resolution information from the resolution information acquiring section 113.
The on period calculating section 102 computes the on period for the light emitting elements (for example, the LEDs) in the backlight 15 on the basis of the video information, luminance information, and resolution information fed from the acquiring sections of the moving image blur video detecting section 101 (detection results for a moving image blur video), and feeds each of the current value calculating section 103 and the driving control section 104 with a PWM signal corresponding to a calculation result.
Note that, in this case, a PWM (Pulse Width Modulation) driving scheme in which turn-on and turn-off are repeated is adopted as a driving scheme for the light emitting elements such as LEDs used in the backlight 15 and thus that PWM signals are output that correspond to the on period for the light emitting elements such as LEDs.
The current value calculating section 103 computes a current value on the basis of the relationship between the PWM signal (on period fed from the on period calculating section 102 and a luminance to be displayed, and feeds a corresponding calculation result to the driving control section 104. Here, the current value, the on period, and the luminance have a relationship as represented by Formula (1) below.
Luminance=f(current value)×on period (1)
Here, in Formula (1), f (current value) is a function for an increase in luminance associated an increase in current value. For example, in the liquid crystal display apparatus 10, for which the backlight 15 using LEDS as the light emitting elements is adopted, the relationship between the current and brightness does not vary linearly. This is due to reduced light emission efficiency caused by self-heating of the LEDs included in the backlight 15, and f (current value) in Formula (1) needs to be a function for which this property is taken into account.
The driving control section 104 is fed with the PWM signal (on period) from the on period calculating section 102 and the current value from the current value calculating section 103. The driving control section 104 generates a driving control signal (BL driving control signal) for turning on the backlight 15 and feeds the driving control signal to the backlight driving section 14 (
Thus, the backlight driving section 14 drives the backlight 15 on the basis of the driving control signal (BL driving control signal) from the driving control section 104.
Note that, with reference to
However, in the self-luminous display apparatus 20, in a case where the configuration illustrated in
Example of Driving with Peak Luminance Information Taken into Account
Incidentally, for example, in the liquid crystal display apparatus 10, the backlight 15 can be configured such that what is called a direct backlight is adopted to provide two-dimensionally arranged plurality of partial light emitting sections. The partial light emitting sections can include, for example, a plurality of light emitting elements such as LEDs. Additionally, each of the partial light emitting sections can independently emit light at a set luminance.
In the liquid crystal display apparatus 10 with the backlight 15 of this type, for each partial light emitting section, when the partial light emitting section is driven, driving is performed in which surplus power for a dark portion is used for a bright portion to increase the luminance.
Specifically, as illustrated in
A of
Additionally, a driving method in
Specifically, in the driving methods illustrated in
Thus, the present technology enables control in which, in a case where the video (video content) focuses on the peak luminance (brightness), switching to the impulse driving is avoided even in a case where, for example, the object in the video is moving and where the video (video content) includes many edge portions (even in a case where a moving image blur video is detected) as in the driving method illustrated in
Flow of Impulse Driving Determination Processing
Now, with reference to a flowchart in
In step S11, the signal processing section 11 compares a preset threshold for moving image amount determination with the moving image amount in a target video included in the video information acquired by the video information acquiring section 111 to determine whether or not the moving image amount in the target video is large.
In step S11, in a case where the moving image amount is smaller than the threshold, that is, in a case where the moving image amount is determined to be small, for example, the target video is a still image, and thus the processing is advanced to step S14. In step S14, the signal processing section 11 controls the backlight driving section 14 to cause the backlight 15 to be driven on the basis of the normal driving.
Here, the normal driving is the driving method illustrated in A of
Additionally, in step S11, in a case where the moving image amount is larger than the threshold, that is, in a case where the moving image amount is determined to be large, for example, the processing is advanced to step S12. In step S12, a preset threshold for edge portion determination is compared with (the amount of edge portions indicated by) the edge amount in the target video included in the resolution information acquired by the resolution information acquiring section 113 to determine whether or not the target video includes many edge portions.
In step S12, in a case where the edge amount is smaller than the threshold, that is, in a case where the video includes few edge portions, the processing is advanced to step S14, and the signal processing section 11 causes the backlight 15 to be driven on the basis of the normal driving (S14).
Additionally, in step S12, in a case where the edge amount is larger than the threshold, that is, in a case where the video includes many edge portions, the processing is advanced to step S13. In step S13, the signal processing section 11 determines whether or not to perform the driving focuses on the brightness. Here, whether or not to perform the driving with the brightness focused on is determined depending on whether or not to perform the driving illustrated in
In step S13, in a case where the driving with the brightness focused on is determined to be performed, the processing is advanced to step S14, and the signal processing section 11 causes the backlight 15 to be driven on the basis of the normal driving (S14).
Here, in a case where the driving illustrated in
Additionally, in step S13, in a case where the driving with the brightness not focused on is determined to be performed, the processing is advanced to step S15. In step S15, the signal processing section 11 causes the backlight 15 to be driven on the basis of the impulse driving.
Here, the impulse driving (impulse type driving) is the driving method illustrated in B of
The flow of the impulse driving determination processing has been described. Note that the order of the steps of determination processing (S11, S12, and S13) in the impulse driving determination processing is optional and that not all the steps of determination processing need to be executed. Additionally, the threshold for determination can be set to an appropriate value according to various conditions.
Note that the impulse driving determination processing has been described, with reference to
Additionally, in the above description, the feature amounts in the video content, that is, the video information, luminance information, and resolution information are illustrated as the feature amounts obtained from the video content. However, any other information may be used as long as the information enables moving image blur is to be detected. Furthermore, in detection of a moving image blur video, not all of the video information, luminance information, and resolution information needs to be used, and it is sufficient to use at least one of the pieces of information.
Additionally, moving image blur is likely to occur in, for example, a video content captured at a low frame rate of 60 Hz or the like. For such a video content including moving image blur (videos with dull edges), a time resolution is not improved even in a case where the impulse driving is performed in a case where a large moving image amount is detected. Thus, in the impulse driving determination processing, execution of the impulse driving can be avoided in a case where the video content is detected, on the basis of the video information and the resolution information. This avoids execution of unnecessary impulse driving, allowing prevention of an excessive increase in power or heat and suppression of a reduction in device life.
As described above, in the first embodiment, the feature amounts such as the video information, the luminance information, and the resolution information are detected as the feature amounts of the video content, and on the basis of the detection results for the feature amounts, control is performed on the driving of the light emitting section such as the backlight 15 (for example, the LEDs) of the liquid crystal display section 13 or the self-luminous elements (for example, the OLEDs) in the self-luminous display section 23.
Thus, according to the degree at which moving image blur is easily visible, control can be performed on the on period and current value for the backlight 15 of the liquid crystal display section 13 and the pixel on period (on period for the self-luminous elements) and current value for the self-luminous display section 23, allowing moving image blur (hold blur) to be removed. As a result, optimal image quality compatible with the displayed video can be provided.
In a second embodiment, a video included in a video content is divided into several regions, and for each of the regions resulting from the division, the driving of the light emitting section (on period and current value) is controlled using a driving method similar to the driving method in the first embodiment described above. Specifically, the simultaneous occurrence of moving image blur over the entire region is rare, and by performing the impulse driving on the region of moving objects, power consumption and shortening of the device life can be reduced.
Configuration of Signal Processing Section
In
That is, compared to the configuration of the signal processing section 11 in
The moving image blur video detecting section 201 includes the video information acquiring section 111, the luminance information acquiring section 112, the resolution information acquiring section 113, and a video region dividing section 211.
The video region dividing section 211 divides a video included in a video content in a plurality of regions, on the basis of a video signal input to the video region dividing section 211, and feeds the video information acquiring section 111, the luminance information acquiring section 112, and the resolution information acquiring section 113 with video signals for videos resulting from the division.
The video information acquiring section 111 executes video information acquisition processing on the video signal for each division region fed from the video region dividing section 211, and feeds a corresponding processing result to the on period calculating section 102 as video information (for example, the moving image amount).
The luminance information acquiring section 112 executes luminance information acquisition processing on the video signal for each division region fed from the video region dividing section 211, and feeds a corresponding processing result to the on period calculating section 102 as luminance information (for example, the peak luminance).
The resolution information acquiring section 113 executes resolution information acquisition processing on the video signal for each division region fed from the video region dividing section 211, and feeds a corresponding processing result to the on period calculating section 102 as resolution information (for example, the edge amount).
The video information, luminance information, and resolution information thus detected by the moving image blur video detecting section 201 are the feature amounts of each division region in each video of the video content, that is, the feature amounts obtained from the division region, and a moving image blur video is detected in the division region on the basis of the feature amounts. Note that
The on period calculating section 102, the current value calculating section 103, and the driving control section 104 generate a driving control signal (BL driving control signal) for turning on (the LEDs in) the backlight 15, on the basis of the detection result for a moving image blur video from the moving image blur video detecting section 101 as described for the configuration in
Note that the configuration of the signal processing section 11 (
Concept of Impulse Driving
In
Here, it is assumed that the entirety of the video 531 illustrated in
As described above, moving image blur may occur while objects in the video are moving, and thus, in this case, the impulse driving is performed on the video in the second region 541B including the moving objects (cars). On the other hand, the normal driving is performed on the video in the first region 541A including no moving object.
Specifically, in the entirety of the video 531 illustrated in
That is, in the driving method in B of
Additionally, in the driving method in B of
Accordingly, the simultaneous occurrence of moving image blur over the entire region in the video 531 is rare, and by performing the impulse driving only on the video in the second region 541B including traveling cars, power consumption and shortening of the device life can be reduced.
Note that
Additionally, in regard to the size of each division region, in
Furthermore, in the above description, the impulse driving determination is performed using only the information obtained from the division regions of the video 531 (first region 541A and second region 541B). However, the current value and on period for each division region may be determined by, for example, adding the information obtained from the division regions (in other words, local information) to the information obtained from the entire region of the video 531.
For example, in a case where, in the impulse driving determination, objects in one division region are determined not to be moving, whereas objects in the other division region are determined to be moving, when the objects in the entire region are determined to be moving, the objects in the video can be determined to be moving, comprehensively on the basis of the determination results, allowing the impulse driving to be performed.
As described above, when the feature amounts such as the video information, the luminance information, and the resolution information are detected as the feature amounts of the video content and on the basis of the detection results for the feature amounts, control is performed on the driving of the light emitting section such as the backlight 15 (for example, the LEDs) of the liquid crystal display section 13 or the self-luminous elements (for example, the OLEDs) in the self-luminous display section 23, the entire region of the video is divided into several regions, and the driving of the light emitting section is controlled for each division region.
Thus, according to the degree at which moving image blur is easily visible, control can be performed on the on period and current value for the backlight 15 of the liquid crystal display section 13 and the pixel on period (on period for the self-luminous elements) and current value for the self-luminous display section 23, allowing moving image blur to be more appropriately removed (hold blur) and enabling further optimization of the image quality, minimization of the power consumption, and extension of the device life.
In recent years, for the backlight 15 in the liquid crystal display apparatus 10, attention has been paid to an LED backlight for which a KSF fluorescent substance (K2SiF6:Mn4+) is adopted. The use of the KSF fluorescent substance is expected to improve the color reproduction range and chroma of the liquid crystal display apparatus 10.
In the third embodiment, a function improving method will be described that is intended for the liquid crystal display apparatus 10 using the LED backlight 15 for which the KSF fluorescent substance is adopted. Note that, in the description below, the LED backlight for which the KSF fluorescent substance is adopted and which is included in the backlight 15 in
Mechanism for Occurrence of Afterimage
With reference to
Here, timing charts in A, C, and D of
Here, for example, as illustrated in
In this case, with the white window 552 in the video 551 focused on, an afterimage is seen that is caused by a delayed response for red (R) between the region of the white portion and the region of the black portion.
Specifically, in a dotted line 561 in
Additionally, in a dotted line 562 in
As described above, in a region of the video 551 that is otherwise displayed in black, white, and black, particularly at the boundary between the black and the white, the white is displayed in cyan or the black is displayed in red, due to the delayed response for read (R). In this case, the region where an afterimage is likely to occur corresponds to, for example, a portion (region) having a long LED off period and a high video contrast. The portion (region) is characterized by the easiness with which the afterimage is visible in the region.
Thus, in the third embodiment, in consideration of RGB response properties exhibited when the LED backlight 15A is used for which the KSF fluorescent substance is adopted, a driving frequency of the impulse driving is changed on the basis of a detection result for afterimage visibility. Thus, control is performed in which the effect of a delayed response for red (R) is mitigated.
First Example of Configuration of Signal Processing Section
In
The video information acquiring section 301 executes video information acquisition processing on the video signal for the video content input to the video information acquiring section 301, and feeds a corresponding processing result to the BL driving control section 303 as video information. In the video information acquisition processing, for example, the visibility of the afterimage included in the video content is detected on the basis of the video signal, with a corresponding detection result output.
The on period calculating section 302 computes the on period for the LEDs in the LED backlight 15A on the basis of the video signal for the video content input to the on period calculating section 302, and feeds the BL driving control section 303 with a PWM signal corresponding to a computation result.
The BL driving control section 303 is fed with the video information from the video information acquiring section 301 and the PWM signal from the on period calculating section 302.
The BL driving control section 303 changes the driving frequency of the PWM signal on the basis of a detection amount for the visibility of an afterimage included in the video information. Additionally, the BL driving control section 303 generates a BL driving control signal corresponding to the result of change of the driving frequency, and feeds the BL driving control signal to the backlight driving section 14 (
Second Example of Signal Processing Section
In
The on period calculating section 312 computes the on period for the LEDs in the LED backlight 15A on the basis of the video signal for the video content input to the on period calculating section 312, and feeds the video information acquiring section 311 and the BL driving control section 303 with a PWM signal corresponding to a computation result.
The video information acquiring section 311 executes video information acquisition processing on the PWM signal fed from the on period calculating section 312, and feeds a corresponding processing result to the BL driving control section 303 as video information. In the video information acquisition processing, the visibility of an afterimage included in the video content is detected on the basis of the PWM signal, with a corresponding detection result output.
The BL driving control section 303 changes the driving frequency for the PWM signal from the on period calculating section 312 on the basis of the detection amount for the visibility of the afterimage included in the video information from the video information acquiring section 311, and generates a BL driving control signal corresponding to the result of the change of the driving frequency. Note that the details of the change of the driving frequency by the BL driving control section 303 will be described below with reference to
Note that, for convenience of description,
That is, as illustrated in
Specifically, the video information acquiring section 301 in
Example of Change of Driving Frequency
A of
Here, compared to the driving method in A of
The driving frequency is increased on the basis of the detection result for the visibility of an afterimage as described above. Then, when an afterimage is caused by a delayed response for red (R), the time (period of time) for which the afterimage is visible can be reduced. Specifically, for example, compared to execution of the driving method in A of
For example, in particular, regions where an afterimage is likely to occur correspond to portions (regions) with a high video contrast, and in such a region, the afterimage caused by the delayed response for red (R) can be reduced by performing the driving based on the driving method in B of
Specifically, for example, a case is assumed that, in the driving method in A of
Note that, when the driving frequency (lighting frequency) illustrated in
Additionally, to prevent a change in luminance of the video, the BL driving control section 303 makes the sum of on periods after a change in driving frequency (the on periods during one frame) substantially the same as on periods before the change in driving frequency (the on periods during one frame). In other words, the BL driving control section 303 makes the on periods before the change in driving frequency equal to the on periods after the change in driving frequency.
As described above, in the third embodiment, when the feature amounts such as the video information, the luminance information, and the resolution information are detected as the feature amounts of the video content, and the on period and current value for (the LEDs in) the LED backlight 15A of the liquid crystal display section 13 are controlled on the basis of the detection results, control is performed in which the effect of the delayed response for red (R) is reduced by changing the driving frequency for the impulse driving on the basis of the detection result for the visibility of the afterimage included in the video information.
Specifically, the liquid crystal display apparatus 10 can determine the degree of the afterimage on the basis of the detection result for the visibility of the afterimage and control the period of lighting of (the LEDs in) the LED backlight 15A to reduce the afterimage according to the determination result. Thus, the liquid crystal display apparatus 10 can change the processing depending on the properties of the LED backlight 15A for which the KSF fluorescent substance is adopted, enabling the adverse effect of the impulse driving to be suppressed.
Incidentally, in the liquid crystal display apparatus 10 (
Concept of Impulse Driving
In
Here, a comparison between the video 901 and the video 902 indicates that both videos include traveling cars but that, in the video 901, a GUI 911 such as a setting menu corresponding to an operation of the viewer/listener is superimposed on the video with the traveling cars.
At this time, the video 901 is a video of a scene in which the cars are traveling, moving image blur may occur, and the viewer/listener pays attention to the GUI 911 on the display screen and is not particularly conscious of the video of the cars behind the GUI 911. Thus, removing moving image blur is unnecessary.
On the other hand, the GUI 911 is not superimposed on the video 902, and the viewer/listener looks at the video of the traveling cars. Thus, as described above, removing moving image blur is needed.
Specifically, in the video 901 on which the GUI 911 is superimposed, the normal driving is performed using the driving method in A of
In other words, in the driving method in B of
In contrast, the driving method in A of
Accordingly, in the fourth embodiment, in a case where the GUI 911 is superimposed on the video 901, the viewer/listener pays attention to the GUI 911, leading to no need for removing moving image blur, and thus the effect removing moving image blur is suppressed. Thus, the liquid crystal display apparatus 10 or the self-luminous display apparatus 20 can suppress an increase in power consumption and a reduction in device life.
Note that GUIs displayed on the liquid crystal display section 13 or the self-luminous display section 23 include a GUI generated by external equipment (for example, a player for reproduction in an optical disc) and a GUI generated inside the liquid crystal display apparatus 10 or the self-luminous display apparatus 20. Thus, a configuration used in a case where the GUI is generated by external equipment is hereinafter illustrated in FIG. 16, and a configuration used in a case where the GUI is generated inside the display apparatus is illustrated in
Configuration of Signal Processing Section
In
In the moving image blur video detecting section 101, the video information acquiring section 111, the luminance information acquiring section 112, and the resolution information acquiring section 113 acquire the video information, the luminance information, and the resolution information as described for the configuration in
The GUI detecting section 61 executes GUI detection processing on the video signal for the video content, and feeds a corresponding processing result to the on period calculating section 102 as the GUI superimposition amount.
The GUI detection processing allows the GUI displayed on the display screen to be detected using information, for example, a moving vector amount between video frames, contrast information, and frequency information. In this case, for example, the superimposition amount of the GUI superimposed on the video displayed on the display screen (for example, the ratio of the region of the GUI to the entire region of the display screen) is detected.
In other words, the GUI detection processing can also be said to include detecting the GUI superimposition amount of the GUI superimposed on the display screen as an example of the graphic amount of graphics. Note that the GUI detection processing may use the feature amount detected by the moving image blur video detecting section 101 (for example, the moving vector amount or the resolution information). Additionally, the details of the GUI detection processing will be described below with reference to
As described above, the GUI superimposition amount detected by the GUI detecting section 611 is a feature amount of the video content. In this case, the effect removing moving image blur is suppressed depending on the GUI superimposition amount. Specifically, the liquid crystal display apparatus 10 suppresses, on the basis of the GUI superimposition amount, the effect removing moving image blur, even in a case where a moving image blur video is detected by the feature amount such as the video information.
The on period calculating section 102, the current value calculating section 103, and the driving control section 104 generate driving control signals (BL driving control signals) for turning on (the LEDs in) the backlight 15 on the basis of the detection result for a moving image blur video from the moving image blur video detecting section 101 and the detection result for the GUI from the GUI detecting section 611 as described for the configuration in
Another Configuration of Signal Processing Section
In
The CPU 1000 operates as a central processing apparatus in the liquid crystal display apparatus 10, for various types of calculation processing, various types of operation control, and the like. In a case where display of the GUI such as the setting menu is indicated, the CPU 1000 acquires, from a memory (not illustrated), the GUI superimposition amount (for example, the size) of the GUI superimposed on the liquid crystal display section 13, and feeds the GUI superimposition amount to the on period calculating section 102. In other words, the GUI superimposition amount (graphic amount) fed from the CPU 1000 is a feature amount of the video content.
The on period calculating section 102, the current value calculating section 103, and the driving control section 104 generate driving control signals (BL driving control signals) for turning on (the LEDs in) the backlight 15 on the basis of the detection result for a moving image blur video from the moving image blur video detecting section 101 and the GUI superimposition amount from the CPU 1000 as described for the configuration in
Thus, in the liquid crystal display apparatus 10, even in a case where a moving image blur video is detected on the basis of the feature amount such as the video information, the effect removing moving image blur is suppressed on the basis of the GUI superimposition amount.
Note that the configuration of the signal processing section 11 of the liquid crystal display apparatus 10 (
Flow of Impulse Driving Determination Processing
Now, with reference to a flowchart in
In steps S31 to S33, as is the case with steps S11 to S13 in
Additionally, in a case where, after the moving image amount is determined to be large in the determination processing in step S31, the number of edge portions is determined to be large in the determination processing in step S32 and further driving with brightness not focused on is determined to be performed in the determination processing in step S33, then the processing is advanced to step S34.
In step S34, the signal processing section 11 determines whether or not the graphic amount such as the GUI superimposition amount of the GUI superimposed on the video is large. For example, in the determination processing in step S34, by comparing a preset threshold for graphic amount determination with the GUI superimposition amount detected by the GUI detecting section 611 (
In step S34, in a case where the graphic amount is larger than the threshold, that is, in a case where the graphic amount is determined to be large, the processing is advanced to step S35. In step S35, the signal processing section 11 causes the backlight 15 to be driven on the basis of the normal driving. A case where the normal driving is performed is assumed to be, for example, a case where the GUI is displayed on the full screen.
Additionally, in step S34, in a case where the graphic amount is smaller than a threshold, that is, in a case where the graphic amount is determined to be small, the processing is advanced to step S36. In step S36, the signal processing section 11 causes the backlight 15 to be driven on the basis of the impulse driving. A case where the impulse driving is performed is assumed to be, for example, a case where the region of the GUI with respect to the entire region of the display screen is small.
The flow of the impulse driving determination processing has been described above. Note that the order of the steps of determination processing (S31, S32, S33, and S34) in the impulse driving determination processing in
Note that the impulse driving determination processing has been described, with reference to
Example of GUI Detecting Method
Now, with reference to
The GUI superimposed on the video is characterized by being displayed in a specific region of the display screen and having a high contrast and clear text contours such that the viewer/listener can easily view the GUI. Now, a method will be described in which, in light of the above-described characteristics, the display screen is divided into a plurality of screen blocks and in which, on the basis of the moving vector amount (movement amount), contrast information, and frequency information obtained from each of the screen blocks, whether or not the GUI is present in the screen block is determined.
In
Here, screen blocks BK (1, 1) to BK (1, 5) in the first row correspond to regions on which a GUI 941 is superimposed. Furthermore, a screen block BK (2, 1) in the second row, a screen block BK (3, 1) in the third row, and a screen block BK (4, 1) in the fourth row correspond to regions on which the GUI 941 is superimposed.
Additionally, for screen blocks BK (2, 2) to BK (2, 5) in the second row, a screen block BK (3, 2) in the third row, a screen block BK (4, 2) in the fourth row, and screen blocks BK (5, 1) and BK (5, 2) in the fifth row, the GUI 941 is superimposed on a part of the region of each screen block BK. Note that the screen blocks BK other than the screen blocks BK listed here correspond to regions on which the GUI 941 is not superimposed.
As described above, screen blocks BK on which the GUI 941 is superimposed are mixed with screen blocks BK on which the GUI 941 is not superimposed. In this case, whether or not the GUI 941 is present in each screen block BK is determined on the basis of the movement amount, contrast information, and frequency information obtained for each screen block BK.
In
The local video information acquiring section 621 executes local video information acquisition processing on the video signal for the video content, and feeds a corresponding processing result to the GUI determining section 624 as local video information.
In the local video information acquisition processing, the local video information is obtained by, for example, detecting, for each screen block, the moving image amount as an indicator representing the movement of an object in the video using the moving vector amount and the like.
The local contrast information acquiring section 622 executes local contrast information acquisition processing on the video signal for the video content, and feeds a corresponding processing result to the GUI determining section 624 as local contrast information.
In the local contrast information acquisition processing includes, for example, for each screen block, comparing a reference region and a comparative region included in the video in each screen block to determine a difference between the darkest portion and the brightest portion, thus obtaining local contrast information.
The local frequency information acquiring section 623 executes local frequency information acquisition processing on the video signal for the video content, and feeds a corresponding processing result to the GUI determining section 624 as local frequency information.
The local frequency information acquisition processing includes, for example, for each screen block, converting the video in each screen block into a spatial frequency band and applying a predetermined filter (for example, a wide band pass filter or the like) to the spatial frequency band, thus obtaining local frequency information.
The GUI determining section 624 is fed with local video information from the local video information acquiring section 621, local contrast information from the local contrast information acquiring section 622, and local frequency information from the local frequency information acquiring section 623.
The GUI determining section 624 determines, for each screen block, whether or not the GUI is superimposed on the screen block on the basis of the local video information, the local contrast information, and the local frequency information. The GUI determining section 624 feeds the on period calculating section 102 (
The GUI determination processing includes executing predetermined calculation processing, for example, on the basis of the local video information, the local contrast information, and local frequency information to determine, for each screen block, the GUI superimposition amount (for example, the ratio of the region of the GUI to the entire region of the display screen) quantitatively representing whether or not the GUI is superimposed on the screen block. Then, the effect removing moving image blur is suppressed according to the GUI superimposition amount as described above.
Note that, in this case, according to the GUI superimposition amount obtained for each screen block, the effect removing moving image blur may be suppressed for the entire display screen or for each division region in a case where the impulse driving is performed for each division region as in the second embodiment. In this case, as the division region, for example, a region corresponding to the screen block BK illustrated in
As described above, in the fourth embodiment, the feature amounts of the video content are detected, and when driving of the light emitting section such as the backlight 15 (for example, the LEDs) of the liquid crystal display section 13 or the self-luminous element (for example, OLED) of the self-luminous display section 23 is controlled on the basis of corresponding detection results, control for suppressing the effect removing moving image blur is performed in a case where graphics such as the GUI are superimposed on the video. Thus, an increase in power consumption and a reduction in device life can be suppressed.
Incidentally, the self-luminous display apparatus 20 poses a problem in that the self-luminous elements (for example, the OLEDs) included in the pixels two-dimensionally arranged in the self-luminous display section 23 are locally degraded, thus degrading the display quality for videos. Here, with focus placed on an increased current applied to the self-luminous elements in pixels driven in accordance with high-luminance, high-chroma video signals, in a case where an increased current is thus applied to many pixels, local degradation of the device is inhibited by suppressing the effect removing moving image blur.
Concept of Impulse Driving
In
In this case, the video 951 is a video including colorful flowers and being high both in luminance and in chroma. That is, since the video 951 is high both in luminance and in chroma, the current applied to the self-luminous elements increases to locally degrade the device, suppressing the effect removing moving image blur.
On the other hand, the video 961 is a video including a map in a dull color (fuliginous color) and being low both in luminance and in chroma. That is, since the video 961 is low both in luminance and in chroma, preventing the device from being locally degraded, suppressing the effect removing moving image blur is unnecessary.
Specifically, in the video 951 being high both in luminance and in chroma, the normal driving is performed on the basis of the driving method in A of
In other words, the driving method in B of
In contrast, the driving method in A of
In the fifth embodiment, in consideration of the life of the self-luminous display section 23 (device) in which the pixels including the self-luminous elements (for example, the OLEDs) are two-dimensionally arranged, the self-luminous display apparatus 20 suppresses the effect removing moving image blur, for a pattern including many pixels having an applied current with a large current value, as described above. This enables local degradation of the device to be suppressed.
Note that, for the applied current, determination may be made on the basis of the level of current applied to the pixel (pixel level) rather than using the information related to luminance or chroma. Thus, a configuration using the information related to luminance or chroma is illustrated in
Configuration of Signal Processing Section
In
In the moving image blur video detecting section 101, the video information acquiring section 111, the luminance information acquiring section 112, and the resolution information acquiring section 113 acquire the video information, the luminance information, and the resolution information as described for the configuration in
The chroma information acquiring section 711 executes chroma information acquisition processing on the video signal for the video content, and feeds a corresponding processing result to the on period calculating section 102 as chroma information.
Here, the chroma information is a value indicating the vividness of the entire video, and the chroma information acquisition processing includes acquiring chroma information on the basis of chroma for each of the regions included in the video (for example, the regions corresponding to the pixels). Note that as the chroma information, for example, a statistical value (for example, a mean, a median, a mode, or a total value) for the chroma for each region may be computed.
Additionally, the luminance information used to suppress the effect removing moving image blur is acquired by the luminance information acquiring section 112, and is a value indicating a property related to the brightness of the entire video. In other words, the luminance information in this case differs from the peak luminance information described above.
As described above, the chroma information acquired by the chroma information acquiring section 711 and the luminance information acquired by the luminance information acquiring section 112 are feature amounts of the video content, and in this case, suppress the effect removing moving image blur. Specifically, in the self-luminous display apparatus 20, even in a case where a moving image blur video is detected on the basis of the feature amount such as the video information, when the number of pixels in the pattern having an applied current with a large current value is determined to be large on the basis of the luminance information and the chroma information, the effect removing moving image blur is suppressed.
The on period calculating section 102, the current value calculating section 103, and the driving control section 104 generate driving control signals (OLED driving control signals) for turning on the self-luminous elements (for example, the OLEDs) in the self-luminous display section 23 on the basis of the detection result for a moving image blur video from the moving image blur video detecting section 101, and the luminance information from the luminance information acquiring section 112 and the chroma information from the chroma information acquiring section 711 as described for the configuration in
Note that
Another Configuration of Signal Processing Section
In
In the moving image blur video detecting section 101, the video information acquiring section 111, the luminance information acquiring section 112, and the resolution information acquiring section 113 acquire the video information, the luminance information, and as described for the configuration in
The pixel level generating section 712 executes pixel level generation processing on the video signal for the video content, and feeds a corresponding processing result to the on period calculating section 102 and the current value calculating section 103 as the pixel level.
In the pixel level generation processing, for example, in a case where each pixel has an RGBW four-color pixel structure in which each pixel includes subpixels for RGB three primary colors and a white (W) subpixel, a level corresponding to an RGBW signal is generated for each pixel. Additionally, the pixel level is correlated with the applied current applied to (the self-luminous element included in) the pixel, and can thus be also said to be applied current information related to the applied current.
The on period calculating section 102, the current value calculating section 103, and the driving control section 104 generate driving control signals (OLED driving control signals) for turning on the self-luminous elements (for example, the OLEDs) in the self-luminous display section 23 on the basis of the detection result for a moving image blur video from the moving image blur video detecting section 101 and the pixel level from the pixel level generating section 712.
Flow of Impulse Driving Determination Processing
Now, with reference to a flowchart in
In steps SM to S53, as is the case with steps S11 to S13 in
Additionally, in a case where, after the moving image amount is determined to be large in the determination processing in step SM, the number of edge portions is determined to be large in the determination processing in step S52 and further driving with brightness not focused on is determined to be performed in the determination processing in step S53, then the processing is advanced to step S54.
In step S54, the signal processing section 21 determines whether or not the number of pixels having an applied current larger than a threshold is large.
In the determination processing in step S54, by comparing a preset threshold for applied current determination with the luminance information acquired by the luminance information acquiring section 112 (
In a case where, in step S54, the number of pixels with an applied current larger than the threshold is determined to be large, the processing is advanced to step S55. In step S55, the signal processing section 21 causes the self-luminous elements in the self-luminous display section 23 to be driven on the basis of the normal driving. A case where the normal driving is performed is assumed to be, for example, a case where a video including a colorful object is displayed.
Additionally, in step S54, in a case where the number of pixels having an applied current larger than the threshold is determined to be small, the processing is advanced to step S56. In step S56, the signal processing section 21 causes the self-luminous elements in the self-luminous display section 23 to be driven on the basis of the impulse driving. A case where the impulse driving is performed is assumed to be, for example, a case where a video including an object in a dull color is displayed.
The flow of the impulse driving determination processing has been described above. Note that the order of the steps of determination processing (SM, S52, S53, and S54) in the impulse driving determination processing in
As described above, in the fifth embodiment, when the feature amounts of the video content are detected, and on the basis of the detection results, the driving of the self-luminous elements (for example, the OLEDs) in the self-luminous display section 23 is controlled, in a case where the applied current to the self-luminous elements increases, control is performed in which the effect removing moving image blur is suppressed. Therefore, the self-luminous display apparatus 20 enables local degradation of the device to be suppressed in the self-luminous display section 23.
The CPU 1000 operates as a central processing apparatus in a liquid crystal display apparatus 10, for various calculation processing and operation control for each section.
Additionally, the CPU 1000 is connected to, for example, a short-range radio communication module or an infrared communication module not illustrated. The CPU 1000 receives an operation signal transmitted from a remote controller (not illustrated) in accordance with an operation of the viewer/listener, and controls the operation of each section in accordance with the received operation signal. Note that as the short-range radio communication, communication complying with Bluetooth (registered trademark) is performed.
For example, in a case where the viewer/listener operates a remote controller to make desired settings, then under the control of the CPU 1000, a GUI (graphics) such as a setting menu corresponding to the operation signal from the remote controller is displayed on the liquid crystal display section 13. Additionally, at this time, the CPU 1000 can feed (the signal processing section 11 (
A power supply section 1001 is connected to an external AC power supply, converts the received AC power supply into a DC power supply with a predetermined voltage, and provides the DC power supply to a DC/DC converter 1002. The DC/DC converter 1002 DC/DC-converts a power supply voltage supplied from the power supply section 1001, and supplies the power voltage converted to different sections including the driving section 1003 and a system on chip 1013. The power supply voltage supplied to the different sections may vary with the section or may be the same.
On the basis of a video signal fed from the system on chip 1013, the driving section 1003 drives the liquid crystal display section 13 and the backlight 15 to cause the liquid crystal display section 13 and the backlight 15 to display the video. Note that the driving section 1003 corresponds to the signal processing section 11, display driving section 12, and backlight driving section 14 illustrated in
HDMI terminals 1004-1 to 1004-3 each transmit and receive signals complying with HDMI (registered trademark) (High Definition Multimedia Interface) standards, to and from external equipment (for example, a player for optical disc reproduction) to which the terminal is connected. On the basis of a control signal complying with the HDMI standards, an HDMI switch 1005 appropriately switches the HDMI terminals 1004-1 to 1004-3 to relay an HDMI signal between the system on chip 1013 and the external equipment connected to the HDMI terminals 1004-1 to 1004-3.
An analog AV input terminal 1006 causes an analog AV (Audio and Visual) signal from the external equipment to be input and fed to the system on chip 1013. An analog sound output terminal 1007 outputs an analog sound signal fed from the system on chip 1013 to external equipment to which the system on chip 1013 is connected.
A USB (Universal Serial Bus) terminal input section 1008 is a connector to which a USB terminal is connected. For example, a storage apparatus such as a semiconductor memory or an HDD (Hard Disk Drive) is connected to the USB terminal input section 1008 as an external apparatus to transmit and receive signals complying with the USB standards to and from the system on chip 1013.
A tuner 1009 is connected to an antenna (not illustrated) via an antenna terminal 1010, and acquires a broadcast signal of a predetermined channel from a radio wave received by the antenna and feeds the broad cast signal to the system on chip 1013. Note that the radio wave received by the tuner 1009 is, for example, a broadcast signal for terrestrial digital broadcasting.
A B-CAS (registered trademark) card 1012 in which an encryption key for unscrambling the terrestrial digital broadcasting is stored is inserted into a CAS card I/F 1011. The CAS card I/F 1011 reads the encryption key stored in the B-CAS card 1012 and feeds the encryption key to the system on chip 1013.
The system on chip 1013 executes processing, for example, processing for an A/D (Analog to Digital) conversion of video signals and sound signals, unscramble processing, and decode processing on broadcast signals.
An audio amplifier 1014 amplifies an analog sound signal fed from the system on chip 1013, and feeds the analog sound signal amplified to a speaker 1015. The speaker 1015 outputs a sound corresponding to the analog sound signal from the audio amplifier 1014.
A communication section 1016 is configured as a communication module supporting radio communication for radio LAN (Local Area Network), wired communication for Ethernet (registered trademark), or cellular-based communication (for example, LTE-Advanced or 5G). The communication section 1016 connects to external equipment, a server, and the like via a network such as a home network or the Internet to transmit and receive various data to and from the system on chip 1013.
Note that the configuration of the liquid crystal display apparatus 10 illustrated in
Additionally, in
In the above-described description, the signal processing section 11 has been described as being included in the liquid crystal display apparatus 10, but the signal processing section 11 can be considered as an independent apparatus and configured as a signal processing apparatus 11 including the moving image blur video detecting section 101, the on period calculating section 102, the current value calculating section 103, and the driving control section 104. In that case, in the above description, the “signal processing section 11” may be replaced with the “signal processing apparatus 11.”
Similarly, the signal processing section 21 has been described as being included in the self-luminous display apparatus 20, but the signal processing section 21 can be considered as an independent apparatus and configured as a signal processing apparatus 21. In that case, in the above description, the “signal processing section 21” may be replaced with the “signal processing apparatus 21.”
Additionally, the electronic equipment using the liquid crystal display apparatus 10 or the self-luminous display apparatus 20 may be, for example, a television receiver, a display apparatus, a personal computer, a tablet type computer, a smartphone, a cellular phone, a digital camera, a head-mounted display, or a game machine, but no such limitation is intended.
For example, the liquid crystal display apparatus 10 or the self-luminous display apparatus 20 may be used as a display section of in-vehicle equipment such as car navigation or a rear seat monitor or wearable equipment such as a watch type or an eyeglass type. Note that the display apparatus includes, for example, a medical monitor, a broadcasting monitor, or a display for digital signage.
Additionally, the video contents include various contents, for example, broadcast contents transmitted by territorial broadcasting, satellite broadcasting, or the like, communication contents streamed via a communication network such as the Internet, and recorded contents recorded in a recording medium such as an optical disc or a semiconductor memory.
Note that a plurality of pixels is two-dimensionally arranged in the liquid crystal display section 13 of the liquid crystal display apparatus 10 and the self-luminous display section 23 of the self-luminous display apparatus 20 but that the pixel arrangement structure is not limited to a specific pixel arrangement structure. For example, besides pixels including RGB three-primary-color subpixels, the pixel arrangement structure may be an RGBW four-color pixel structure including RGB three-primary-color subpixels and a white (W) subpixel or an RGBY four-color pixel structure including RGB three-primary-color subpixels and a yellow (Y) subpixel.
Additionally, in the above description, the liquid crystal display section 13 and the self-luminous display section 23 have been described, but no limitation to those display sections is imposed. The present configuration may be used for any other display section, for example, an MEMS (Micro Electro Mechanical Systems) display including a TFT (Thin Film Transistor) substrate on which an MEMS shutter is driven.
Furthermore, as the type of the backlight 15 of the liquid crystal display section 13, for example, a direct type or an edge light type (light guide plate type) may be adopted. Here, in a case where the direct type is adopted as the type of the backlight 15, not only may the partial driving (driving in units of blocks) be used that is performed by the partial light emitting section 151 illustrated in
Note that the embodiments of the present technology are not limited to the above-described embodiments and that various changes may be made to the embodiments without departing from the spirits of the present invention. For example, as a detection method for the feature amounts detected by the moving image blur video detecting section 101 and a detection method for the GUI detected by the GUI detecting section 611, well-known techniques can be used to apply various detection methods.
Additionally, the present technology can be configured as follows.
(1) A signal processing apparatus including:
(2) The signal processing apparatus according to (1), further including:
(3) The signal processing apparatus according to (2), in which
(4) The signal processing apparatus according to (3), in which
(5) The signal processing apparatus according to (3) or (4), in which
(6) The signal processing apparatus according to any one of (3) to (5), in which
(7) The signal processing apparatus according to any one of (4) to (6), in which
(8) The signal processing apparatus according to any one of (4) to (7), in which
(9) The signal processing apparatus according to (7) or (8), in which
(10) The signal processing apparatus according to any one of (3) to (9), in which
(11) The signal processing apparatus according to any one of (2) to (10), in which
(12) The signal processing apparatus according to (11), in which
(13) The signal processing apparatus according to any one of (3) to (9), in which
(14) The signal processing apparatus according to (13), in which
(15) The signal processing apparatus according to any one of (3) to (12), in which
(16) The signal processing apparatus according to (15), in which
(17) The signal processing apparatus according to (15) or (16), in which
(18) The signal processing apparatus according to (17), in which
(19) The signal processing apparatus according to (3) to (12), in which
(20) The signal processing apparatus according to (19), in which
(21) The signal processing apparatus according to (20), in which
(22) A signal processing method for a signal processing apparatus, in which
(23) A display apparatus including:
10 Liquid crystal display apparatus, 11 Signal processing section, 12 Display driving section, 13 Liquid crystal display section, 14 Backlight driving section, 15 Backlight, 15A LED backlight, 20 Self-luminous display apparatus, 21 Signal processing section, 22 Display driving section, 23 Self-luminous display section, 101 Moving image blur video detecting section, 102 On period calculating section, 103 Current value calculating section, 104 Driving control section, 111 Video information acquiring section, 112 Luminance information acquiring section, 113 Resolution information acquiring section, 151, 151A, 151B Partial light emitting section, 201 Moving image blur video detecting section, 211 Video region dividing section, 301 Video information acquiring section, 303 BL driving control section, 311 Video information acquiring section, 312 On period calculating section, 611 GUI detecting section, 621 Local video information acquiring section, 622 Local contrast information acquiring section, 623 Local frequency information acquiring section, 624 GUI determining section, 711 Chroma information acquiring section, 712 Pixel level generating section, 1000 CPU, 1003 Driving section
Number | Date | Country | Kind |
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2017-242425 | Dec 2017 | JP | national |
2018-233115 | Dec 2018 | JP | national |
The present application is a continuation of U.S. patent application Ser. No. 16/771,485, filed on Jun. 10, 2020, which is a national phase entry under 35 U.S.C. § 371 of International Application No. PCT/JP2018/046119, filed on Dec. 14, 2018, which claims the priority from Japanese Patent Application No. 2017-242425, filed in the Japanese Patent Office on Dec. 19, 2017, and Japanese Patent Application No. 2018-233115, filed in the Japanese Patent Office on Dec. 13, 2018, the disclosures of which are hereby incorporated herein by reference.
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