JP2013161083A - Video display device and television receiver - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform a high quality video expression free from strange feeling constantly by detecting a light emitting section of a video signal, by enhancing a display luminance of the light emitting section to conspicuously display, and by controlling a luminance stretch according to an image quality mode set at this time.SOLUTION: An emitted light detecting section 12 detects a light emitting section which is regarded as emitting light on the basis of a predetermined feature quantity of an input video signal. An area active control and luminance stretch section 14 stretches and increases a luminance of a backlight section 16 on the basis of an indicator related to brightness calculated from the input video signal according to a predetermined condition, and decreases a luminance of a video signal of a non-light emitting section except the light emitting section. At this time, the area active control and luminance stretch section 14 switches a control curve for determining a relationship between the indicator related to the brightness and a stretch amount according to an image quality mode set by an image quality mode setting section 19.

Description

  The present invention relates to a video display device and a television receiver, and more particularly, to a video display device and a television receiver having a luminance stretch function of a video signal and a backlight light source in order to improve the quality of a displayed video.

  In recent years, with regard to the display technology of a television receiver, a technology related to HDR (high dynamic range imaging) that faithfully reproduces and displays what exists in nature has been actively studied. One of the purposes of HDR is, for example, to reproduce a luminescent color portion such as fireworks or neon in a screen, and to give a sense of brightness.

  In this case, the emission color and the object color can be detected and separated by the emission detection function, and only the emission color on the screen can be brightened by signal processing and backlight emission luminance control. Here, in a video that changes variously, a portion that emits light relatively brightly is detected from the luminance distribution of the video, and the light emitting portion is consciously stretched to make the light emitting portion on the screen more prominent. The effect of improving the image quality can be obtained.

  As a conventional technique, for example, Patent Document 1 discloses a display device for realizing an appropriate screen display luminance corresponding to video content and sufficiently reducing power consumption. This liquid crystal display device changes the luminance conversion characteristic that defines the light emission luminance of the backlight light source with respect to the feature amount (for example, APL) of the input video signal in accordance with the image quality mode set in the device. At this time, the luminance conversion characteristic can be further changed according to the brightness detected by the brightness sensor.

Japanese Patent Laid-Open No. 2007-140436

As described above, in the HDR technology, by detecting a light emitting portion that is brightly shining on the screen and stretching the display luminance of the light emitting portion, the contrast is improved for the human eye, and the brightness It is possible to provide a high-quality display image.
Here, some video display apparatuses can set various image quality modes. By arbitrarily setting the image quality mode, a preset image quality adjustment process is performed and video display is performed. Examples of such image quality modes include, for example, a dynamic mode that emphasizes a feeling of brightness, a standard mode that targets standard image quality, a movie mode for viewing movie content, and a PC (Personal Computer) that is output. PC mode for viewing the contents.

The appearance of the display screen displayed on the video display device changes according to the setting of the image quality mode. At this time, if the HDR is operated under certain conditions regardless of the state of the image quality mode, some images may be dazzled and uncomfortable, or so-called black float may be noticeable and the quality may be lowered.
For example, when the movie mode is set on the video display device, for example, the user tries to watch movie content with a relatively dark screen for a long time. In such a case, if the screen brightness is uniformly increased by the signal processing by HDR and the brightness stretch of the backlight, the feeling of dazzling is strong and tiredness may occur even though the user is trying to watch carefully. In addition, in movie content with many dark screens, so-called black floating becomes noticeable due to HDR luminance stretch, and the visual quality may deteriorate. In such different image quality modes, the image quality corresponding to each image quality mode is required, so if the luminance stretch is uniformly performed by HDR, depending on the video content and environment, the image may be uncomfortable due to the dazzling feeling, Degradation of image quality may occur due to black float.

  The video display device of Patent Document 1 changes the luminance conversion characteristic that defines the light emission luminance of the backlight light source with respect to the feature amount of the input video signal according to the set image quality mode. The brightness at that time is not stretched, and the light-emitting area in the screen is particularly highlighted to make it brighter.At this time, the degree of brightness stretch can be controlled according to the image quality mode to reduce glare. However, the idea of preventing the deterioration of the image quality due to the black float is not disclosed.

  The present invention has been made in view of the above circumstances, and by detecting the light emitting portion of the video signal and stretching the display luminance of the light emitting portion to display it, the brightness can be further enhanced. An image display device that performs display with higher contrast and controls the luminance stretch according to the image quality mode set in the image display device at this time, and always displays a high-quality image without a sense of incongruity, and An object is to provide a television receiver.

  In order to solve the above-described problems, a first technical means of the present invention includes a display unit that displays an input video signal, a light source that illuminates the display unit, a display unit, and a control unit that controls the light source. The control unit is based on a control curve that defines a relationship between a brightness-related index calculated based on a predetermined condition from the input video signal and a brightness stretch amount for stretching the brightness of the light source. The luminance of the light source is stretched to increase, and the video signal of the non-light emitting part excluding the light emitting part is detected based on the predetermined feature amount of the input video signal, and the light emitting part regarded as the light emitting picture is detected. The image display device enhances the display luminance of the light emitting unit by reducing the luminance of the image display device, and the image display device includes an image quality mode setting unit that sets an image quality mode of the image display device, Control unit is in accordance with the set image quality mode setting unit image quality mode, in which is characterized in that switching the control curve.

  The second technical means is a television receiver provided with the video display device of the first technical means.

  According to the present invention, the light emitting portion of the video signal is detected, and the display brightness of the light emitting portion is stretched to be displayed out of the display, thereby increasing the brightness and displaying with high contrast. In addition, by controlling the luminance stretch according to the image quality mode set in the video display device, it is possible to provide a video display device and a television receiver that can always perform high-quality video expression without a sense of incongruity.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure explaining one Embodiment of the video display apparatus based on this invention, and shows the structure of the principal part of a video display apparatus. It is a figure explaining the control process of the light emission area | region in an area active control and a brightness stretch part. It is another figure explaining the control process of the light emission area | region in an area active control and brightness | luminance stretch part. It is a figure explaining the determination process of an average lighting rate concretely. It is a figure for demonstrating the process example of an area active control and a brightness | luminance stretch part. It is a figure which shows the example of the Y histogram produced | generated from the luminance signal Y. It is a figure which shows an example of the tone mapping which a mapping part produces | generates. It is a figure for demonstrating the Max brightness | luminance output by an area active control and brightness | luminance stretch part. It is a figure for demonstrating the example of control of the Max brightness | luminance changed according to image quality mode. It is a figure for demonstrating the other example of control of the Max brightness | luminance changed according to image quality mode. It is a figure for demonstrating the further another example of control of the Max brightness | luminance changed according to image quality mode. It is a figure for demonstrating the further another example of control of the Max brightness | luminance changed according to image quality mode. It is a figure explaining the 1st threshold value and 2nd threshold value which are changed according to image quality mode. It is a figure explaining the example of the tone mapping which changes according to image quality mode. It is a figure explaining the other example of the tone mapping which changes according to image quality mode. It is a figure explaining the further another example of the tone mapping which changes according to image quality mode. It is a figure explaining the further another example of the tone mapping which changes according to image quality mode. It is a figure which shows the state in which screen brightness | luminance is enhanced by the process of area active control and the brightness | luminance stretch part. It is a figure explaining 2nd Embodiment of the video display apparatus which concerns on this invention. An example of a Y histogram generated from a luminance signal Y of an input video signal is shown. It is a figure which shows the example of calculation of the luminance stretch amount according to the pixel more than a 3rd threshold value. It is a figure for demonstrating the example of a setting of the control curve of a luminance stretch amount. It is a figure for demonstrating the other example of a control curve of the luminance stretch amount changed according to image quality mode. It is a figure for demonstrating the other example of a setting of the control curve of the luminance stretch amount changed according to an image quality mode. It is a figure for demonstrating the other example of a setting of the control curve of the luminance stretch amount changed according to an image quality mode. It is a figure explaining the example of the tone mapping which changes according to image quality mode. It is a figure explaining the other example of the tone mapping which changes according to image quality mode. It is a figure explaining the further another example of the tone mapping which changes according to image quality mode. It is a figure explaining the further another example of the tone mapping which changes according to image quality mode. It is a figure explaining other embodiment of the video display apparatus concerning this invention. It is a figure for demonstrating the method of calculating CMI from the broadcast video signal which should be displayed with a video display apparatus. It is a figure for demonstrating the maximum gradation value of RGB used as a feature-value.

(Embodiment 1)
FIG. 1 is a diagram for explaining an embodiment of a video display device according to the present invention, and shows a configuration of a main part of the video display device. The video display device has a configuration in which an input video signal is subjected to image processing to display a video, and can be applied to a television receiver or the like.
The video signal separated from the broadcast signal and the video signal input from the external device are input to the signal processing unit 11 and the area active control / luminance stretch unit 14. At this time, the tone mapping generated by the mapping unit 13 of the signal processing unit 11 is applied to the video signal to the area active control / luminance stretch unit 14 and then input to the area active control / luminance stretch unit 14.

  The light emission detection unit 12 of the signal processing unit 11 generates a histogram for each frame based on the feature amount of the input video signal, and detects a light emitting part. The light emitting portion is obtained from the average value and standard deviation of the histogram, and is detected as a relative value for each histogram.

The image quality mode setting unit 19 sets the image quality mode of the video display device and outputs the setting information to the light emission detection unit 12 and the area active control / luminance stretch unit 14. Examples of the image quality mode include a dynamic mode, a standard mode, a movie mode, and a PC mode. The characteristics of each image quality mode and a control example at this time will be described later.
The image quality mode setting in the image quality mode setting unit 19 can be set by a user operation using the operation input unit 20. The operation input unit 20 allows a user to perform a predetermined operation input, and can be configured by, for example, a remote controller or a group of keys or buttons (not shown) provided on the main body of the video display device.

  The mapping unit 13 generates tone mapping using the information on the light emission part detected by the light emission detection unit 12 and the Max luminance output from the area active control / luminance stretch unit 14, and applies it to the input video signal. To do. The Max luminance indicates the maximum luminance desired to be displayed on the screen and corresponds to the luminance stretch amount of the backlight.

  The area active control / luminance stretch unit 14 divides the image based on the video signal into predetermined areas according to the input video signal, and extracts predetermined statistical values such as the maximum gradation value of the video signal for each divided area. Then, the lighting rate of the backlight unit 16 is calculated based on the maximum gradation value and the like. The lighting rate is determined for each area of the backlight unit 16 corresponding to the divided area of the video. Moreover, the backlight part 16 is comprised by several LED, and brightness | luminance control is possible for every area | region.

The lighting rate for each area of the backlight unit 16 is determined based on a predetermined arithmetic expression, but is basically maintained without reducing the luminance of the LED in an area having a bright maximum gradation value of high gradation. Then, an operation is performed to reduce the luminance of the LED in a dark area with low gradation.
Then, the area active control / luminance stretch unit 14 calculates the overall average lighting rate of the backlight unit 16 from the lighting rate of each region, and according to the average lighting rate, the area of the backlight unit 16 is calculated by a predetermined arithmetic expression. Calculate brightness stretch amount. As a result, the maximum luminance value (Max luminance) that can be taken in the area in the screen is obtained. Here, the Max luminance is determined based on the setting information of the image quality mode by the image quality mode setting unit 19 and is output to the mapping unit 13 of the signal processing unit 11.

Then, the area active control / luminance stretch unit 14 returns the Max luminance determined according to the image quality mode set in the image quality mode setting unit 19 to the signal processing unit 11 and corresponds to the luminance stretch of the backlight unit 16. Reduce the brightness.
At this time, the luminance stretch is applied to the entire backlight unit 16, and the luminance reduction due to the video signal processing is performed on the portion regarded as not emitting light except the light emitting unit. As a result, the screen brightness of only the light emitting portion can be increased, video can be expressed with high contrast, and the image quality can be improved.

The area active control / luminance stretch unit 14 outputs control data for controlling the backlight unit 16 to the backlight control unit 15, and the backlight control unit 15 selects the LEDs of the backlight unit 16 based on the data. The emission luminance is controlled for each divided area. Although the brightness | luminance of LED of the backlight part 16 is performed by PWM (Pulse Width Modulation) control, it can be controlled so that it may become a desired value by current control or these combination.
The area active control / luminance stretch unit 14 outputs control data for controlling the display unit 18 to the display control unit 17, and the display control unit 17 controls the display of the display unit 18 based on the data. . The display unit 18 is a liquid crystal panel that is illuminated by the LED of the backlight unit 16 and displays an image.

  In the present embodiment, the control unit of the present invention controls the backlight unit 16 and the display unit 18, and includes a signal processing unit 11, an area active control / luminance stretch unit 14, a backlight control unit 15, and The display control unit 17 corresponds.

  When the display device is configured as a television receiving device, the television receiving device has means for selecting and demodulating a broadcast signal received by an antenna, and decoding and generating a reproduction video signal. The signal is appropriately subjected to predetermined image processing and input as the input video signal of FIG. Thereby, the received broadcast signal can be displayed on the display unit 18. The present invention can be configured as a video display device and a television receiver including the video display device.

Hereinafter, a processing example of each unit of the present embodiment having the above-described configuration will be described more specifically.
The area active control / luminance stretch unit 14 divides the video into a plurality of predetermined areas (areas), and controls the emission luminance of the LEDs corresponding to the divided areas for each area. 2 to 3 are diagrams for explaining the light emission region control processing in the area active control / luminance stretch unit 14. Area active control applied to the present embodiment divides an image into a plurality of predetermined areas (areas), and controls the light emission luminance of the LED corresponding to the divided areas for each area.

  Here, the area active control / luminance stretch unit 14 divides one frame of video into a plurality of predetermined areas based on the input video signal, and extracts the maximum gradation value of the video signal for each of the divided areas. To do. For example, an image as shown in FIG. 2A is divided into a plurality of predetermined areas. Here, the maximum gradation value of the video signal in each region is extracted. In another example, other statistical values such as the average gradation value of the video signal may be used instead of the maximum gradation value. Hereinafter, an example in which the maximum gradation value is extracted will be described.

  The area active control / luminance stretch unit 14 determines the lighting rate of the LED for each area according to the extracted maximum gradation value. FIG. 2B shows the lighting rate of the LEDs in each region at this time. In a bright portion where the gradation of the video signal is high, a bright display is performed by increasing the lighting rate of the LED. The process at this time will be described more specifically.

  An example of a state when the maximum gradation value of each divided region of one frame is extracted is shown in FIG. In FIG. 3, it is assumed that the screen of one frame is divided into eight regions (regions <1> to <8>) in order to simplify the description. FIG. 3A shows the lighting rate of each region (regions <1> to <8>), and FIG. 3B shows the lighting rate of each region and the average lighting rate of the entire screen. Here, the lighting rate of the backlight LED in each region is calculated from the maximum gradation value in each region. The lighting rate can be indicated by, for example, the LED drive duty. In this case, the lighting rate Max is 100%.

In determining the lighting rate of the LED in each region, the luminance of the backlight is lowered by lowering the lighting rate in a dark region where the maximum gradation value is low. As an example, when the gradation value of the video is represented by 8-bit data of 0-255, when the maximum gradation value is 128, the backlight is (1 / (255/128)) ^2.2 = 0. Reduce to 217 times (21.7%).
In the example of FIG. 3, the lighting rate of the backlight is determined in the range of 10 to 90% for each region. This lighting rate calculation method shows an example. Basically, a bright high gradation region does not decrease the backlight luminance, and the backlight luminance is decreased in advance in a low gradation dark region. The lighting rate of each area is calculated according to the determined arithmetic expression.
Then, the backlight lighting rate for each region calculated from the maximum gradation value of the video signal is averaged to calculate the average lighting rate of the backlight in one frame. In this example, the average lighting rate is the level of the average lighting rate shown in FIG. The average lighting rate is an example of an index related to brightness according to the present invention.

  FIG. 4 is a diagram for explaining the average lighting rate determination process more specifically. As described above, in the determination of the lighting rate of the LED in each region, the luminance of the backlight is lowered by lowering the lighting rate in a dark region where the maximum gradation value is low. Here, the actual lighting rate of each region is determined so that the gradation to be displayed is accurately displayed and the LED duty is made as low as possible. The LED duty in each area is desired to be as low as possible, but it is necessary to display accurately without squashing the gradation to be displayed. Therefore, an LED that can display the maximum gradation in the area and lowers the LED duty as much as possible. The duty (temporary lighting rate) is set, and the gradation of the display unit 9 (LCD panel here) is set based on the duty.

As an example, when the gradation value of the video is expressed by 8-bit data of 0 to 255, the gradation values of a plurality of pixels in one region in FIG. 3A are shown in FIG. The case indicated by will be described. Here, it is assumed that nine pixels correspond to one region. In the pixel group shown in FIG. 4A, the maximum gradation value is 128. In this case, as shown in FIG. 4B, the lighting rate of the backlight in that region is (1 / (255/128). )) ^2.2 = 0.217 times (21.7%).

  As an example, the area active control / luminance stretch unit 5 determines the lighting rate in this way, and calculates the gradation value for each pixel in the display unit 9 in consideration of the lighting rate for the region including the pixel. . For example, when the gradation value to be displayed is 96, since 96 / (128/255) = 192, the pixel may be expressed using the gradation value 192. Similarly, FIG. 4C shows the result of calculating the gradation value for display for each pixel in FIG.

The actual luminance of the backlight unit 16 is further stretched and enhanced based on the value of the Max luminance determined according to the average lighting rate. The original reference luminance is, for example, such luminance that the screen luminance is 550 (cd / m ² ) at the maximum gradation value. The reference luminance can be appropriately determined without being limited to this example.

FIG. 5 is a diagram for explaining a processing example of the area active control / luminance stretch unit 14. As described above, the area active control / luminance stretch unit 14 calculates the average lighting rate of the entire screen from the lighting rate determined according to the maximum gradation value of each region. The average lighting rate of the entire screen increases as the number of areas with high lighting rates increases. Then, the maximum luminance value (Max luminance) that can be taken is determined based on the relationship shown in FIG. The horizontal axis represents the backlight lighting rate (window size), and the vertical axis represents the screen luminance (cd / m ² ) at the Max luminance. The average lighting rate can be expressed as a ratio between a lighting region (window region) with a lighting rate of 100% and a light-off region with a lighting rate of 0%. The lighting rate is zero when there is no lighting region, the lighting rate increases as the window of the lighting region increases, and the lighting rate becomes 100% with full lighting.

In FIG. 5, the Max luminance when the backlight is fully lit (average lighting rate 100%) is, for example, 550 (cd / m ² ). Then, the Max luminance is increased as the average lighting rate decreases. At this time, a pixel having a gradation value of 255 gradations (in the case of 8-bit representation) has the highest screen brightness in the screen, and the maximum possible screen brightness (Max brightness). Therefore, it can be seen that even with the same average lighting rate, the screen luminance does not increase up to the Max luminance depending on the gradation value of the pixel.

When the average lighting rate is Q1, the value of Max luminance is the largest, and the maximum screen luminance at this time is 1500 (cd / m ² ). That is, at Q1, the maximum possible screen brightness is stretched to 1500 (cd / m ² ) compared to 550 (cd / m ² ) when all the lights are on. Q1 is set at a position where the average lighting rate is relatively low. In other words, the brightness of the backlight is stretched to a maximum of 1500 (cd / m ² ) when the screen is a dark screen as a whole with a low average lighting rate and a high gradation peak in part. Also, the reason for the lower stretch of backlight brightness is the higher the average lighting rate, the less bright the screen is because it may feel dazzling if the backlight brightness is excessively high on an originally bright screen. It is for doing so.

From the average lighting rate Q1 with the maximum Max luminance to the average lighting rate 0 (all black), the value of Max luminance is gradually decreased. In the predetermined area where the average lighting rate is the lowest, the screen brightness is further reduced from 550 (cd / m ² ) at the time of full lighting. In other words, the screen brightness is stretched to a negative value when the entire lighting is used as a reference. The range where the average lighting rate is low corresponds to the image of a dark screen. Rather than stretching the backlight brightness to increase the screen brightness, the backlight brightness is reduced to improve the contrast. Reduce black float and maintain display quality.

  The area active control / luminance stretch unit 14 stretches the luminance of the backlight according to the curve of FIG. 5 and outputs the control signal to the backlight control unit 15. Here, as described above, the average lighting rate changes according to the maximum gradation value detected for each divided region of the video, and the state of the luminance stretch changes according to the average lighting rate.

  The video signal input to the area active control / luminance stretch unit 14 is applied with tone mapping generated by signal processing performed by the signal processing unit 11 described below, and the low gradation region is gain-down and input. As a result, the luminance of the backlight is stretched in the low gradation non-light emitting area, and the luminance is reduced by the video signal processing. As a result, the screen luminance is enhanced only in the light emitting area, and the brightness is increased. It has become.

  The area active control / luminance stretch unit 14 maps the Max luminance value determined from the average lighting rate of the backlight and the image quality mode setting information from the image quality mode setting unit 19 according to the curve of FIG. To the unit 13. The mapping unit 13 performs tone mapping using the Max luminance output from the area active control / luminance stretch unit 14.

The signal processing unit 11 will be described.
The light emission detection unit 12 of the signal processing unit 11 detects a light emitting part from the video signal. FIG. 6 shows an example of a Y histogram generated from the luminance signal Y. The light emission detector 12 adds up the number of pixels for each luminance gradation for each frame of the input video signal to generate a Y histogram. The horizontal axis represents the gradation value of luminance Y, and the vertical axis represents the number of pixels (frequency) integrated for each gradation value. The luminance Y is one of the feature quantities of the video for creating the histogram, and other examples of the feature quantities will be described later. Here, it is assumed that a light emitting portion is detected for luminance Y.
When the Y histogram is generated, an average value (Ave) and a standard deviation (σ) are calculated from the Y histogram, and two threshold values Th are calculated using these.

The second threshold value Th2 defines a light emission boundary, and processing is performed on the assumption that pixels above the threshold value Th2 in the Y histogram are light emitting portions.
The second threshold Th2 is
Th2 = Ave + Nσ Expression (1)
And N is a predetermined constant.

The first threshold Th1 is set to suppress a sense of incongruity such as gradation in an area smaller than Th2.
Th1 = Ave + Mσ Expression (2)
And M is a predetermined constant, and M <N. The value of M changes according to the image quality mode set in the image quality mode setting unit 19.
The values of the first and second threshold values Th1 and Th2 detected by the light emission detection unit 12 are output to the mapping unit 13 and used to generate tone mapping.

  FIG. 7 is a diagram illustrating an example of tone mapping generated by the mapping unit 13. The horizontal axis is the input gradation of the luminance value of the video, and the vertical axis is the output gradation. The pixels detected by the light emission detector 12 that are equal to or greater than the second threshold Th2 are portions that emit light in the video, and the gain is reduced by applying a compression gain except for the portions that emit light. At this time, if the output gradation is suppressed by uniformly applying a constant compression gain to a region smaller than Th2, which is the light emission boundary, a sense of incongruity occurs in the gradation. Therefore, the light emission detection unit 12 sets and detects the first threshold Th1, sets the first gain G1 for a region smaller than Th1, and sets the second gain so as to linearly connect Th1 and Th2. Tone mapping is performed by setting the gain G2.

A method for setting the gain will be described.
The mapping unit 13 receives the Max luminance value from the area active control / luminance stretch unit 14. As described above, the Max luminance indicates the maximum luminance determined from the average lighting rate of the backlight and the image quality mode setting information by the image quality mode setting unit 19, and is input as, for example, a backlight duty value. .

The first gain G1 is applied to a region smaller than the first threshold Th1,
G1 = (Ls / Lm) ^{1 / γ} Expression (3)
Is set by Ls is reference luminance (reference luminance when the backlight luminance is not stretched; for example, luminance when the maximum screen luminance is 550 cd / m ² ), and Lm is output from the area active control / luminance stretching unit 14 Max luminance. Therefore, the first gain G1 applied to the region smaller than the first threshold Th1 lowers the output gradation of the video signal so as to reduce the screen luminance that increases due to the luminance stretch of the backlight.

For tone mapping of the second threshold Th2 or more, f (x) = x. That is, input gradation = output gradation, and processing for lowering the output gradation is not performed. Between the first threshold Th1 and the second threshold Th2, the output gradation of the first threshold Th1 lowered by the first gain G1 and the output gradation of the first threshold Th1 are connected by a straight line. Set as follows.
That means
G2 = (Th2-G1 · Th1) / (Th2-Th1) (4)
To determine the second gain G2.
Through the above processing, tone mapping as shown in FIG. 7 is obtained. At this time, with respect to the connecting portions of Th1 and Th2, a predetermined range (for example, connecting portion ± Δ (Δ is a predetermined value)) may be smoothed by a quadratic function.

  The tone mapping generated by the mapping unit 13 is applied to the input video signal, and the video signal in which the output of the low gradation part is suppressed based on the luminance stretch amount of the backlight is input to the area active control / luminance stretch unit 14.

FIG. 8 is a diagram for explaining the Max luminance output by the area active control / luminance stretch unit 14.
The area active control / luminance stretch unit 14 receives the video signal to which the tone mapping generated by the mapping unit 13 is applied, performs area active control based on the video signal, and determines Max luminance based on the average lighting rate. . At this time, the Max luminance control curve changes according to the image quality mode setting information from the image quality mode setting unit 19, but the image quality mode is not considered here for the sake of explanation.

  The frame determined based on the above average lighting rate is N frame. The value of the Max luminance of the N frame is output to the mapping unit 13 of the signal processing unit 11. The mapping unit 13 generates tone mapping as shown in FIG. 7 using the inputted Max luminance of the N frame and applies it to the video signal of the N + 1 frame.

  Thus, Max luminance based on the area active average lighting rate is fed back and used for tone mapping of the next frame. The mapping unit 13 applies a gain (first gain G1) for reducing the video output for an area smaller than the first threshold Th1, based on the Max luminance determined in N frames. The second gain G2 that linearly connects Th1 and Th2 is applied to the region between Th1 and Th2, and the video output between Th1 and Th2 is reduced.

  Since a gain for reducing the video output in N frames is applied, in a region with a high lighting rate with an average lighting rate of Q1 or more, in N + 1 frames, the maximum gradation value for each region is lowered and the lighting rate is lowered. As a result, Max luminance tends to increase in N + 1 frames. As a result, the luminance stretch amount of the backlight is further increased, and the brightness of the screen tends to increase. However, this tendency is not seen in the region where the lighting rate is lower than Q1, and the opposite tendency.

  Next, processing according to the image quality mode will be described. In the embodiment according to the present invention, the Max luminance control curve corresponding to the average lighting rate as shown in FIG. 5 is changed according to the image quality mode set in the image quality mode setting unit 19.

(Backlight brightness control example based on image quality mode)
As described above, the area active control / luminance stretch unit 14 inputs the video signal to which the tone mapping generated by the mapping unit 13 is applied, performs area active control based on the video signal, and based on the average lighting rate Max brightness is determined. At this time, the area active control / luminance stretch unit 14 varies the Max luminance control curve in accordance with the image quality mode set in the image quality mode setting unit 19. At the same time, the mapping unit 13 shifts the first threshold Th1 and the second threshold Th2 in the direction of the feature amount such as luminance in accordance with the image quality mode set in the image quality mode setting unit 19, and according to the image quality mode. The optimal video display should be performed.

FIG. 9 is a diagram for describing an example of control of Max luminance that is changed according to the image quality mode, and illustrates an example of control of Max luminance when the image quality mode is the dynamic mode.
As described above, the area active control / luminance stretch unit 14 calculates the average lighting rate of the entire screen from the lighting rate determined according to the maximum gradation value of each region. The average lighting rate of the entire screen increases as the number of areas with high lighting rates increases. Then, the maximum luminance value (Max luminance) that can be taken is determined based on the relationship shown in FIG.

At this time, the control curve defining the relationship between the Max luminance and the average lighting rate in FIG. 9 is changed according to the image quality mode set in the image quality mode setting unit 19. FIG. 9 shows an example of the control curve in the dynamic mode.
The dynamic mode is a mode in which, for example, a sports program can be viewed as a powerful video with clear and vivid video. The dynamic mode can be used as a demo mode (also referred to as a storefront mode) for appealing the features of the device, for example, at a point of sale. Usually, the dynamic mode is executed with the best image quality and brightness prepared in the video display device.

As shown in FIG. 9, in the dynamic mode, the maximum value of Max luminance is set high, and the average lighting rate level having the maximum value of Max luminance is set relatively high. For example, when the maximum Max luminance level in the entire range of the average lighting rate is B, the Max luminance level when the average lighting rate is 100% is C, and the average lighting rate having the maximum Max luminance is D, the dynamic mode In the control curve R1, B is set to about 1500 cd / m ² and C is set to about 550 cd / m ² . The position of D is set at a position of about 30% where the average lighting rate is relatively high.

Further, the Max luminance at the lowest lighting rate (lighting rate 0%) is 0 (cd / m ² ), and at this time, the backlight is completely turned off. In other words, if the C level of 550 cd / m ² is used as a reference, the backlight is stretched negatively in a predetermined region with a low lighting rate. In the dynamic mode, B is set to a luminance difference that is approximately three times that of C, and the ratio of B and C is set to the highest among all image quality modes.

In the control curve R1, the maximum luminance value B is set to 1500 cd / m ² and the luminance is greatly stretched to obtain a bright and bright image. In addition, even in a dark video region where the average lighting rate is low, by setting the Max luminance to a certain level, a video with an emphasis on brightness is provided.

  FIG. 10 is a diagram for explaining another control example of the Max luminance that is changed according to the image quality mode, and illustrates an example of the control of the Max luminance when the image quality mode is the standard mode. The standard mode is a mode indicating that the setting of image quality or the like is a standard value, and is a mode mainly intended for use at home. In general, in the standard mode, the emphasis is on the natural expression of the image, and it is considered to be conscious of power saving to some extent.

In the case of the standard mode of FIG. 10, the control curve R2 that defines the relationship between the Max luminance and the average lighting rate is different from the control curve R1 of the dynamic mode of FIG. In the control curve R2 in the standard mode, the maximum value of the Max luminance is set to be lower than that in the dynamic mode. For example, the maximum Max luminance level B in the entire range of the average lighting rate is set to about 700 cd / m ² .
The levels of C and D are the same as those in the dynamic mode, and are set to about 550 cd / m ² and about 30%, respectively. Further, the Max luminance at the lowest lighting rate (lighting rate 0%) is 0 (cd / m ² ) as in the dynamic mode, and at this time, the backlight is completely turned off. In the standard mode, B is set to have a luminance difference of about 1.3 times C.

In the control curve R2 in the standard mode, the maximum brightness B of the maximum brightness B is set to about 700 cd / m ² , and the amount of brightness stretch is suppressed compared to the dynamic mode, so that the display screen is excessively dazzled in a standard viewing environment such as home. While displaying the image, a sharp image is displayed. In the standard mode, the level of the average lighting rate D having the maximum Max luminance is made equal to that in the dynamic mode. Thus, even in a low-dark video region, the Max luminance is maintained to be high to some extent, so that the video is provided with standard brightness although the luminance is not stretched until the dynamic mode.

  FIG. 11 is a diagram for explaining still another control example of the Max luminance that is changed according to the image quality mode, and shows an example of control of the Max luminance when the image quality mode is the movie mode. The movie mode is a mode for expressing a film feeling with an emphasis on faithfully reproducing the video included in the movie source.

In the case of the movie mode of FIG. 11, in the control curve R3 that defines the relationship between the Max luminance and the average lighting rate, the maximum Max luminance level B in the entire range of the average lighting rate is about 700 cd / m, which is about the same as the standard mode. ² . The level of C is set to about 550 cd / m ² as in the dynamic mode and the standard mode. Further, the Max luminance at the lowest lighting rate (lighting rate 0%) is 0 (cd / m ² ) as in the dynamic mode and the standard mode, and at this time, the backlight is completely turned off. In the movie mode, B is set to a luminance difference of about 1.3 times C.

  Here, in the control curve R3 in the movie mode, the average lighting rate having the maximum Max luminance is set to a level lower than the dynamic mode and the standard mode. For example, the average lighting rate of D in the movie mode is about 17%. In this way, compared to the standard mode, by shifting the D level to the low average lighting rate side, it is possible to prevent the viewer from feeling excessively dazzling when watching movie contents and the like, and in the dark area in the divided area. If there is also a peak, that is, it is possible to reproduce the video with an emphasis on the brightness of a relatively small bright area. Also, by reducing the D level, the maximum Max brightness is set when the video is relatively dark, so even when watching video continuously for a long time like movie content, fatigue due to glare It can be prevented from occurring.

  FIG. 12 is a diagram for explaining still another control example of the Max luminance that is changed in accordance with the image quality mode, and shows an example of control of the Max luminance when the image quality mode is the PC mode. The PC mode is a mode in which the video output from the PC is displayed in an optimal image so that it can be easily viewed. is there.

In the case of the PC mode in FIG. 12, the Max luminance is constant regardless of the average lighting rate in the control curve R4 that defines the relationship between the Max luminance and the average lighting rate. The Max luminance level at this time is a standard level of about 550 cd / m ² . That is, in the PC mode, the luminance enhancement process by the light emission detection is substantially turned off. The PC mode emphasizes the reproduction of the fidelity of the video, so that the input video signal is reproduced faithfully without detecting the bright part of the video and performing video processing or performing backlight brightness stretching. To do.

  FIG. 13 is a diagram for describing the first threshold and the second threshold that are changed according to the image quality mode. As described above, the light emission detection unit 12 generates a Y histogram by integrating the number of pixels for each luminance gradation for each frame of the input video signal. Then, an average value (Ave) and a standard deviation (σ) are calculated from the Y histogram, and a second threshold value Th2 for defining a light emission boundary and a first threshold value for suppressing a sense of incongruity such as gradation in an area smaller than Th2. Th1 (Th1 = Ave + Mσ) is set.

  At this time, the position of the first threshold Th1 and the position of the second threshold Th2 in FIG. 13 are changed according to the image quality mode set in the image quality mode setting unit 19. In addition, the position of either the first threshold Th1 or the second threshold Th2 may be changed according to the set image quality mode. Specifically, in the case of the first threshold, the value of “M” of Th1 = Ave + Mσ is changed to change the position of Th1 in the luminance direction of the histogram. In the case of the second threshold, the value of “N” in Th2 = A + Nσ (M <N) is changed to change the position of Th2 in the luminance direction of the histogram.

  For example, as shown in FIG. 13, when the values of M and N are increased according to the image quality mode and the first and second threshold values Th1 and Th2 are shifted to the high luminance side, the sharpness of the image quality in a dark environment is improved. The image quality can be enhanced to emphasize the contrast. On the other hand, when the first and second threshold values Th1 and Th2 are shifted to the low luminance side, it is possible to obtain an image quality that emphasizes the brightness of the screen.

FIG. 14 is a diagram illustrating an example of tone mapping that changes according to the image quality mode, and is a diagram illustrating an example of toe mapping that is set in the dynamic mode.
As described above, the mapping unit 13 sets the first gain G1 for an area smaller than the first threshold Th1, and sets the second gain G2 so as to linearly connect Th1 and Th2, thereby toning the tone. Perform mapping. At this time, tone mapping is performed according to the positions of the first threshold Th1 and the second threshold Th2 determined according to the image quality mode set in the image quality mode setting unit 19. In the dynamic mode, the first threshold value Th1 and the second threshold value Th2 are suppressed to a relatively low level (on the low luminance side of the histogram), and an image that emphasizes brightness is provided.

FIG. 15 is a diagram illustrating another example of tone mapping that changes according to the image quality mode, and is a diagram illustrating an example of toe mapping set in the standard mode.
In the standard mode, the levels of both the first threshold value Th1 and the second threshold value Th2 are increased compared to the dynamic mode in which brightness is important. That is, the first and second threshold values Th1 and Th2 are shifted to the high luminance side of the histogram. Thus, in a standard viewing environment such as a home, a sharp image is displayed while suppressing excessive glare on the display screen.

FIG. 16 is a diagram for explaining still another example of tone mapping that changes in accordance with the image quality mode, and is a diagram illustrating an example of toe mapping set in the movie mode.
In the movie mode, only the first threshold Th1 is set to a higher level as compared with the standard mode. That is, only Th1 is shifted to the high luminance side of the histogram. This emphasizes the sharpness of the image quality in a dark environment and prevents fatigue due to glare.

FIG. 17 is a diagram illustrating still another example of tone mapping that changes in accordance with the image quality mode, and is a diagram illustrating an example of toe mapping set in the PC mode.
As described above, in the PC mode, the luminance enhancement process by the light emission detection is substantially turned off. Accordingly, in tone mapping, the output gradation with respect to the input gradation has the same value.

FIG. 18 is a diagram illustrating a state in which the screen luminance is enhanced by the processing of the area active control / luminance stretch unit 14. The horizontal axis is the gradation value of the input video signal, and the vertical axis is the screen brightness (cd / m ² ) of the display unit 18.
T2 and T3 correspond to the positions of the gradation values of the first and second threshold values Th1 and Th2 used in the light emission detection unit 12, respectively. As described above, the signal processing for reducing the output gradation of the video signal according to the luminance stretch amount of the backlight is not performed in the region of the second threshold Th2 or more detected by the light emission detection unit 12. As a result, in T3 to T4, the input video signal is enhanced and displayed with a γ curve according to the Max luminance determined by the area active control. For example, if the Max luminance is 1500 (cd / m ² ), the screen luminance is 1500 (cd / m ² ) when the input video signal has the highest gradation value (255). The Max luminance in this case is the Max luminance determined according to the average lighting rate determined based on the video signal and the set image quality mode.

  On the other hand, in the case of input gradation values from T1 to T2, as described above, the first gain G1 is applied to the video signal so as to reduce the screen luminance component that increases due to the luminance stretch of the backlight. Therefore, the screen is displayed with a γ curve based on the reference luminance. This is because the output value of the video signal is suppressed in a range smaller than the threshold Th1 (corresponding to T2) corresponding to the luminance stretch by the mapping unit 13 in accordance with the Max luminance determined by the area active control / luminance stretch unit 14. From T2 to T3, the screen luminance changes according to the tone mapping of Th1 to Th2.

When the Max luminance increases, the difference in the screen luminance direction between the curve based on the reference luminance of T1 to T2 and the curve based on the Max luminance of T3 to T4 increases. As described above, the curve based on the reference brightness indicates that the maximum brightness value screen brightness is the reference brightness when the backlight brightness is not stretched (for example, the maximum brightness value screen brightness is 550 cd / m ² ). The curve based on the Max luminance is a γ curve in which the screen luminance of the maximum gradation value becomes the Max luminance determined by the area active control / luminance stretch unit 14.

In this way, when the input video signal is between 0 gradation (T1) and T2, the screen brightness is controlled with the reference brightness. In the case of dark images with low gradation, if the brightness is increased and displayed, the contrast will decrease and the quality of the product such as black floating will decrease. Try not to go up.
In addition, since the range where the input video signal is greater than or equal to T3 is a range that is considered to emit light, the video signal is maintained without being suppressed while the backlight is stretched by luminance stretching. Thereby, the screen brightness is enhanced, and a high-quality image display with a more lustrous feeling can be performed.

  In this case, for example, when the Max luminance is suppressed to a low level according to the image quality mode set in the image quality mode setting unit 19, a curve based on the reference luminance of T1 to T2 and a curve based on the Max luminance of T3 to T4 in the screen luminance direction. The difference becomes smaller. That is, as the Max luminance determined according to the image quality mode set by the image quality mode setting unit 19 is decreased, the curve from T3 to T4 is shifted to the lower luminance side. The positions T2 and T3 correspond to the positions of the first threshold Th1 and the second threshold Th2, which change according to the set image quality mode, respectively. When the positions of T2 and T3 are shifted to the high gradation side of the input signal, display with an emphasis on contrast is achieved. The γ curves from T1 to T2 do not need to match the reference luminance, and can be set by appropriately adjusting the gain G1 as long as it has a level that gives a difference from the enhancement region of the light emitting portion. .

(Embodiment 2)
FIG. 19 is a diagram for explaining a second embodiment of the video display apparatus according to the present invention.
The second embodiment has the same configuration as that of the first embodiment, but unlike the first embodiment, the value of the Max luminance used when performing tone mapping is changed to an area active control / luminance stretch unit. 14, the luminance stretch amount is determined based on the detection result of the light emission detection unit 12 and the image quality mode set in the image quality mode setting unit 19, and tone mapping is executed based on the determined luminance stretch amount. Therefore, the mapping unit 13 of the signal processing unit 11 does not need to output the Max luminance value by luminance stretching from the area active control / luminance stretching unit 14 as in the first embodiment.

  The image quality mode setting unit 19 sets the image quality mode of the video display device according to the operation of the operation input unit 20 or the like, as in the first embodiment. In the second embodiment, information on the set image quality mode is output to the light emission detection unit 12.

  FIG. 20 shows an example of a Y histogram generated from the luminance signal Y of the input video signal. As in the first embodiment, the light emission detection unit 12 uses the luminance as the video feature amount, and generates a Y histogram by integrating the number of pixels for each luminance gradation of each pixel of the input video signal. Then, an average value (Ave) and a standard deviation (σ) are calculated from the Y histogram, and two threshold values Th1 and Th2 are calculated using these values. As in the first embodiment, the second threshold value Th2 defines a light emission boundary, and in the Y histogram, pixels that are equal to or higher than the threshold value Th2 are regarded as light emitting portions. As the feature amount of the video, other feature amounts described later can be used, but here, luminance is used.

In the present embodiment, in addition to the first threshold Th1 and the second threshold Th2 of the first embodiment, a third threshold Th3 is further set. The third threshold value Th3 is between Th1 and Th2, and is provided for detecting the state of the pixel in the light emitting portion.
The threshold value Th3 may be the same value as Th2, but is provided in order to facilitate processing by providing a wider margin for the light emitting portion equal to or greater than Th2.
Therefore,
Th3 = Ave + Qσ (M <Q ≦ N) (5)
It becomes.

式（６）において、count[i]は、階調値ｉについての画素数のカウントである。また、ｉ²−（Thresh3）²は、図２０で示したような輝度についての距離（輝度の差）を指し、代わりに、明度Ｌ^*における閾値からの距離を採用してもよい。なお、この２乗は輝度を表すものであり、実際には２．２乗となる。つまり、デジタルのコード値がｉの場合、輝度はｉ^2.2となる。そのとき、明度Ｌ^*は（ｉ^2.2）^1/3≒ｉとなる。実際の映像表示装置で検証した結果、輝度での閾値からの差が明度での閾値からの差などより効果的であった。
また、式（６）において、全画素数とはｉ＞Ｔｈ３に限らず全ての画素数をカウントした値を指す。スコアとしてこのような計算値を採用すると、発光部分のうちＴｈ３から離れた高階調の画素が多い場合にはスコアが高くなる。また、Ｔｈ３以上の画素数が一定であっても、階調が高い画素が多い方がスコアは高くなる。 FIG. 21 is a diagram illustrating a calculation example of the luminance stretch amount according to the pixel equal to or greater than the third threshold Th3. The horizontal axis represents the score of the pixel value equal to or greater than the threshold Th3, and the vertical axis represents the luminance stretch amount according to the score. The score corresponds to an example of an index related to the brightness of the present invention.
The score is defined as [ratio of pixels greater than or equal to a certain threshold value] × [distance from threshold value (brightness difference)], and counts the number of pixels having gradation values larger than the third threshold value Th3. The degree of brightness is shown by weighting and calculating the distance from, and is calculated by the following equation (6), for example.

In equation (6), count [i] is a count of the number of pixels for the gradation value i. Further, i ² − (Thresh3) ² indicates the distance (brightness difference) with respect to the luminance as shown in FIG. 20, and instead, the distance from the threshold value in the lightness L ^* may be adopted. Note that this square represents the luminance and is actually the 2.2th power. That is, when the digital code value is i, the luminance is i ^2.2 . At that time, the lightness L ^* is (i ^2.2 ) ^1/3 ≈ i. As a result of verification with an actual video display device, the difference from the threshold value in luminance was more effective than the difference from the threshold value in brightness.
In Expression (6), the total number of pixels refers to a value obtained by counting all the numbers of pixels without being limited to i> Th3. When such a calculated value is adopted as the score, the score increases when there are many high gradation pixels apart from Th3 in the light emitting portion. Even if the number of pixels equal to or greater than Th3 is constant, the score increases as the number of pixels with high gradation increases.

When the score is higher than a certain level, the luminance stretch amount is set high, and a high gradation shining image is stretched to a higher luminance to increase the brightness. In this example, in a portion where the score is higher than a certain level, the maximum screen luminance that can be obtained after luminance stretching is set to 1500 (cd / m ² ). When the score is low, the luminance stretch amount is set to be smaller as the score is smaller. The light emission detection unit 12 changes the control curve that defines the relationship between the score and the luminance stretch amount according to the image quality mode set in the image quality mode setting unit 19. This luminance stretch amount is the same concept as the Max luminance of the first embodiment, and is indicated by, for example, a backlight duty value.

FIG. 22 is a diagram for explaining a setting example of the control curve for the luminance stretch amount, and shows an example of controlling the luminance stretch amount when the image quality mode is the dynamic mode.
As described above, the light emission detection unit 12 determines the luminance stretch amount according to the score of the pixel value equal to or greater than the threshold Th3. The control curve that defines the relationship between the score and the luminance stretch amount at this time is used as the image quality mode setting unit. 19 according to the setting information of the image quality mode output from 19.

In the control curve U1 of FIG. 22, the level of the maximum luminance stretch amount in the entire range of the score is E, and the score at the point where the luminance stretch amount starts decreasing from the maximum luminance stretch amount level E as the score decreases is F. To do.
In the control curve U1 in the dynamic mode of FIG. 22, the luminance stretch amount E is set to a high luminance stretch amount of about 1500 cd / m ² , and the score F is set to a relatively low value near the middle of the entire score. In the control curve U1, by setting the luminance stretch amount E to a high level, a bright and brilliant image is obtained. In addition, by setting the score F to be relatively low, an image with an emphasis on brightness is provided.

FIG. 23 is a diagram for explaining another setting example of the control curve for the luminance stretch amount that is changed according to the image quality mode, and shows an example of controlling the luminance stretch amount when the image quality mode is the dynamic mode. . In the control curve U2 of FIG. 23, the maximum luminance stretch amount E is set to be lower, for example, 800 cd / m ^{2 as} compared with the dynamic mode. At this time, the level of the score F is the same as in the dynamic mode, and is set to a relatively low value near the middle of the entire score.

In the control curve U2 in the standard mode, the maximum value E of the luminance stretch amount is about 800 cd / m ^{2 and the} luminance stretch amount is suppressed compared to the dynamic mode, so that the display screen is excessively dazzled in a standard viewing environment such as home. While displaying the image, a sharp image is displayed. In the standard mode, the level of score F is the same as that in the dynamic mode, so that even in low and dark video areas, the brightness stretch amount is kept high to a certain extent, thereby providing video with standard brightness. To do.

FIG. 24 is a diagram for explaining still another setting example of the control curve of the luminance stretch amount that is changed according to the image quality mode, and shows an example of controlling the luminance stretch amount when the image quality mode is the movie mode. is there. In the control curve U3 of FIG. 24, the maximum luminance stretch amount E is set as low as about 800 cd / m ² as in the standard mode. The score F level is set to a value lower than that of the dynamic mode and the standard mode.

  Here, in the movie mode control curve U3, the maximum luminance stretch amount E is set to a level lower than that in the dynamic mode, thereby preventing the viewer from feeling excessively dazzling when watching movie contents and the like. can do. Compared to the standard mode, the F level is shifted to the low score side to prevent the viewer from feeling excessively dazzled when watching movie content and the like, and in the dark in the divided areas. In other words, it is possible to reproduce the video with an emphasis on the brightness of a bright area with a relatively small area.

FIG. 25 is a diagram for explaining yet another setting example of the control curve of the luminance stretch amount that is changed according to the image quality mode, and shows an example of controlling the luminance stretch amount when the image quality mode is the PC mode. is there. In the PC mode, in the control curve U4 that defines the relationship between the score and the luminance stretch amount, the luminance stretch amount is constant regardless of the score value. The level of the luminance stretch amount at this time is a standard level of about 550 cd / m ² . That is, in the PC mode, the luminance enhancement process by the light emission detection is substantially turned off. The PC mode emphasizes the reproduction of the fidelity of the video, so that the input video signal is reproduced faithfully without detecting the bright part of the video and performing video processing or performing backlight brightness stretching. To do.

Next, an example of tone mapping that changes according to the image quality mode will be described.
As described with reference to FIG. 13 in the first embodiment, also in this embodiment, the light emission detection unit 12 integrates the number of pixels for each luminance gradation for each frame of the input video signal. Generate a histogram. Then, an average value (Ave) and a standard deviation (σ) are calculated from the Y histogram, and a second threshold value Th2 for defining a light emission boundary and a first threshold value for suppressing a sense of incongruity such as gradation in an area smaller than Th2. Th1 (Th1 = Ave + Mσ) is set.

  At this time, the position of the first threshold Th1 and the position of the second threshold Th2 are changed according to the image quality mode set in the image quality mode setting unit 19. Alternatively, the position of either the first threshold Th1 or the second threshold Th2 may be changed according to the set image quality mode. Specifically, in the case of the first threshold, the value of “M” of Th1 = Ave + Mσ is changed to change the position of Th1 in the luminance direction of the histogram. In the case of the second threshold, the value of “N” in Th2 = A + Nσ (M <N) is changed to change the position of Th2 in the luminance direction of the histogram. For example, if the values of M and N are increased according to the image quality mode and the first and second threshold values Th1 and Th2 are shifted to the high luminance side, the sharpness of the image quality in a dark environment is emphasized and the contrast is emphasized. Image quality. On the other hand, when the first and second threshold values Th1 and Th2 are shifted to the low luminance side, it is possible to obtain an image quality that emphasizes the brightness of the screen.

FIG. 26 is a diagram illustrating an example of tone mapping that changes according to the image quality mode, and is a diagram illustrating an example of toe mapping that is set in the dynamic mode.
As described above, the mapping unit 13 sets the first gain G1 for an area smaller than the first threshold Th1, and sets the second gain G2 so as to linearly connect Th1 and Th2, thereby toning the tone. Perform mapping. At this time, tone mapping is performed according to the positions of the first threshold Th1 and the second threshold Th2 determined according to the image quality mode set in the image quality mode setting unit 19. In the dynamic mode, the first threshold value Th1 and the second threshold value Th2 are suppressed to a relatively low level (on the low luminance side of the histogram), and an image that emphasizes brightness is provided.

FIG. 27 is a diagram illustrating another example of tone mapping that changes according to the image quality mode, and is a diagram illustrating an example of toe mapping set in the standard mode.
In the standard mode, the levels of both the first threshold value Th1 and the second threshold value Th2 are increased compared to the dynamic mode in which brightness is important. That is, the histogram is shifted to the high luminance side. Thus, in a standard viewing environment such as a home, a sharp image is displayed while suppressing excessive glare on the display screen.

FIG. 28 is a diagram illustrating still another example of tone mapping that changes in accordance with the image quality mode, and is a diagram illustrating an example of toe mapping set in the movie mode.
In the movie mode, only the first threshold Th1 is set to a higher level as compared with the standard mode. That is, only Th1 is shifted to the high luminance side of the histogram. This emphasizes the sharpness of the image quality in a dark environment and prevents fatigue due to glare.

FIG. 29 is a diagram illustrating still another example of tone mapping that changes in accordance with the image quality mode, and is a diagram illustrating an example of toe mapping set in the PC mode.
As described above, in the PC mode, the luminance enhancement process by the light emission detection is substantially turned off. Accordingly, in tone mapping, the output gradation with respect to the input gradation has the same value.

The tone mapping obtained by the above processing is applied to the input video signal and input to the area active control / luminance stretch unit 14.
The processing in the area active control / luminance stretch unit 14 is the same as in the first embodiment. However, the area active control / luminance stretch unit 14 does not need to determine the Max luminance from the average lighting rate of the backlight and output it to the signal processing unit 11 as in the first embodiment, and conversely, the light emission of the signal processing unit 11 Based on the luminance stretch amount output from the detection unit 12, the luminance of the LED of the backlight unit 16 is stretched.

  That is, the area active control / luminance stretch unit 14 divides the video into a plurality of predetermined areas (areas), extracts the maximum gradation value of the video signal for each of the divided areas, and according to the extracted maximum gradation value. The LED lighting rate for each area is determined. For example, in a dark region where the maximum gradation value is low, the lighting rate is lowered to lower the backlight luminance. In this state, the input power of the entire backlight is increased in accordance with the luminance stretch amount output from the light emission detection unit 12, and the entire luminance of the backlight is increased. As a result, the bright image that is emitted becomes brighter and more radiant. Further, since the luminance corresponding to the luminance stretch is reduced by the video signal processing in the non-light-emitting portion, as a result, the luminance of only the light-emitting portion is increased on the screen, and a high-contrast high-quality image is displayed. be able to. The relationship between the input video signal and the screen luminance is the same as that in FIG. 18 shown in the first embodiment.

(Embodiment 3)
FIG. 30 is a diagram for explaining still another embodiment of the video display apparatus according to the present invention.
The third embodiment has the same configuration as the second embodiment and performs the same operation as the second embodiment. However, unlike the second embodiment, the luminance stretch unit 21 performs area active control. Without performing, the luminance of the backlight unit 16 is stretched based on the luminance stretch amount output from the light emission detection unit 12 of the signal processing unit 11.

  That is, the luminance stretch unit 21 inputs the video signal to which the tone mapping generated by the mapping unit 13 is applied, and outputs control data for displaying the video signal to the display control unit 17. At this time, processing by area active control is not performed. On the other hand, the entire backlight unit 16 is stretched uniformly based on the luminance stretch amount output from the light emission detection unit 12.

As a result, the bright image that is emitted becomes brighter and more radiant. In addition, since the luminance corresponding to the luminance stretch is reduced by the video signal processing in the non-light emitting part, as a result, the luminance of the light emitting part is increased on the screen, and high contrast and high quality images are displayed. Can do.
Since the operation of the other components in the third embodiment is the same as that of the second embodiment, repeated description is omitted.

(Other features)
In each of the above examples, the luminance Y is used as the feature amount of the light emission unit detection processing in the light emission detection unit 12, a luminance histogram is generated, and the light emission unit is detected therefrom. As a feature value for generating a histogram, for example, CMI (Color Mode Index) or MaxRGB can be used in addition to luminance.

CMI is an index indicating how bright the color of interest is. Here, the CMI is different from the luminance, and indicates the brightness in consideration of the color information. CMI is
L * / L * modeboundary × 100 (7)
Defined by

  The L * is an indicator of relative color brightness, and when L * = 100, the brightness of the brightest white as the object color is obtained. In the above formula (7), L * is the brightness of the color of interest, and L * modeboundary is the brightness of the boundary that appears to emit light with the same chromaticity as the color of interest. Here, it is known that L * modeboundary≈lightness of the brightest color (the brightest color of the object color). The lightness of the color where CMI = 100 is called the emission color boundary, and it is defined as emitting light when CMI = 100 is exceeded.

  A method for calculating the CMI from the broadcast video signal to be displayed on the video display device will be described with reference to FIG. The broadcast video signal is standardized based on the BT.709 standard and transmitted. Accordingly, the RGB data of the broadcast video signal is first converted into tristimulus value XYZ data using a conversion matrix for BT.709. Then, the brightness L * is calculated from Y using a conversion formula. It is assumed that the color L * of interest is at position J1 in FIG. Next, the chromaticity is calculated from the converted XYZ, and the L * (L * modeboundary) of the brightest color having the same chromaticity as the target color is examined from the already known brightest color data. The position on FIG. 31 is J2.

From these values, the CMI is calculated using the above equation (7). CMI is indicated by the ratio of L * of the target pixel and L * (L * modeboundary) of the brightest color of the chromaticity.
The CMI is obtained for each pixel of the video signal by the above method. Since it is a standardized broadcast signal, all pixels have a CMI in the range of 0-100. Then, for one frame image, a CMI histogram is created with the horizontal axis as CMI and the vertical axis as frequency. Here, the average value Ave. and the standard deviation σ are calculated, and each threshold value is set to detect the light emitting portion.

  In another example, the feature amount is data (MaxRGB) having the maximum gradation value among RGB data. In the combination of RGB, the fact that two colors have the same chromaticity is synonymous with the fact that the ratio of RGB does not change. That is, the process of calculating the brightest color of the same chromaticity in the CMI is a process of obtaining a combination of RGB when the gradation of the RGB data becomes the maximum when the RGB data is multiplied by a certain value without changing the ratio.

For example, a pixel having gradation RGB data as shown in FIG. When the RGB data of the pixel of interest is multiplied by a certain number, as shown in FIG. 32B, when RGB is first saturated, the color is the brightest color with the same chromaticity as the original pixel. When the gradation of the target pixel of the first saturated color (in this case R) is r1, and the gradation of the brightest color R is r2,
r1 / r2 × 100 (8)
A value similar to CMI can be obtained. The color that first saturates when it is multiplied by a certain value to RGB is the color having the maximum gradation among the RGB of the pixel of interest.

  Then, a value is calculated according to the above equation (8) for each pixel to create a histogram. An average value Ave. and a standard deviation σ are calculated from this histogram, and each threshold value is set to detect a light emitting portion, or to detect a black amount. The histogram at this time may be obtained by integrating the RGB maximum gradation values of the pixels without converting them to values of 0 to 100 according to Equation (8).

DESCRIPTION OF SYMBOLS 11 ... Signal processing part, 12 ... Light emission detection part, 13 ... Mapping part, 14 ... Area active control / luminance stretch part, 15 ... Backlight control part, 16 ... Backlight part, 17 ... Display control part, 18 ... Display part 19, image quality mode setting unit, 20 ... operation input unit, 21 ... luminance stretch unit.

Claims (2)

A display unit that displays an input video signal, a light source that illuminates the display unit, a control unit that controls the display unit and the light source,
The control unit adjusts the luminance of the light source based on a control curve that defines a relationship between a brightness-related index calculated from the input video signal based on a predetermined condition and a luminance stretch amount for stretching the luminance of the light source. Stretch and increase,
Based on a predetermined feature amount of the input video signal, a light emitting unit that is regarded as a light emitting image is detected, and the luminance of the video signal of the non-light emitting unit excluding the light emitting unit is reduced, thereby the light emitting unit An image display device that enhances the display brightness of
The video display device has an image quality mode setting unit for setting an image quality mode of the video display device,
The video display device, wherein the control unit switches the control curve according to an image quality mode set in the image quality mode setting unit.   A television receiver comprising the video display device according to claim 1.

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