JP2021141349A - Video processing apparatus and video processing method - Google Patents

Abstract

To reduce blackout and improve the image quality.SOLUTION: A BD player 1 includes a playback unit 4 that acquires content information, and a video processing unit 5 that converts a video signal on the basis of luminance distribution of a content included in the content information acquired by the playback unit 4. The video processing unit 5 lifts and expands data in the dark part of the video signal, and compresses data in the bright part of the video signal. The video processing unit 5 sets the minimum brightness of the content, the maximum brightness of the content, and the maximum frame average brightness on the basis of the content information acquired by the playback unit 4, and sets the upper limit of the brightness of the extending dark part to the dark part upper limit brightness.SELECTED DRAWING: Figure 2

Description

The present invention relates to a video processing device that performs video signal processing on a video signal, and a video processing method.

In recent years, HDR contents corresponding to high-brightness HDR (High Dynamic Range) have appeared. Since HDR content has a wide dynamic range, it may exceed the range that the monitor can properly display depending on the content. In this case, monitors such as LCDs (Liquid Crystal Display) and projectors, whose depiction of dark areas is unstable in principle, gain a range mainly at the expense of reproducibility of dark areas (by causing so-called black crushing). There is. However, since the reproducibility of dark areas is an important factor of image quality, black crushing has a large effect on image quality, and is regarded as a problem.

FIG. 7 is a graph showing an example of black crushing. The horizontal axis shows the video signal, and the vertical axis shows the brightness [cd / m ² ]. FIG. 7B is an enlarged view of the vicinity of the arrow in FIG. 7A. As shown in the figure, the brightness is constant in a specific range, and black crushing occurs. The applicant has applied for a patent for an invention for preventing gradation collapse (black collapse and whiteout) (see Patent Document 1).

Japanese Unexamined Patent Publication No. 2018-046317

As described above, the prior art has a problem that black crushing occurs.

An object of the present invention is to reduce black crushing and improve image quality.

The video processing device of the first invention includes an acquisition unit that acquires content information and a video processing unit that converts a video signal based on the brightness distribution of the content included in the content information acquired by the acquisition unit. The video processing unit is characterized in that the data in the dark part of the video signal is lifted and expanded, and the data in the bright part of the video signal is compressed.

In the present invention, the video processing unit expands by lifting the data in the dark part of the video signal and compresses the data in the bright part of the video signal. As a result, it is possible to reduce black crushing and improve image quality.

The video processing apparatus of the second invention is the video processing apparatus of the first invention, wherein the video processing unit has a minimum brightness of the content, a maximum brightness of the content, and the maximum brightness of the content based on the content information acquired by the acquisition unit. , The maximum frame average brightness is set, and the upper limit value of the brightness of the extended dark part is set to the upper limit brightness of the dark part.

The video processing device of the third invention is the video processing device of the first or second invention, and the video processing unit does not convert the video signal when the minimum brightness of the content is equal to or higher than the upper limit brightness of the dark part. It is characterized by.

The video processing device of the fourth invention is the video processing device of any one of the first to third inventions, and the video processing unit converts a video signal when the minimum brightness of the content is smaller than the upper limit brightness of the dark part. It is characterized by doing.

The video processing device of the fifth invention is the video processing device of any one of the first to fourth inventions, and the video processing unit sets a code value of a video signal according to EOTF (Electro-Optical Transfer Function). After converting to a value, the video signal is converted.

The video processing apparatus of the sixth invention is the video processing apparatus of the fifth invention. It is characterized by converting to a value.

The video processing apparatus of the seventh invention is the video processing apparatus of any one of the first to sixth inventions, wherein the video processing unit lifts and expands the data of the dark part of the video signal up to the upper limit brightness of the dark part. , A constant value is added, and the coefficient is set so as to increase with a gradient of 1 or more.

The video processing apparatus of the eighth invention is the video processing apparatus of any one of the first to seventh inventions, wherein the video processing unit changes the code value of the video signal corresponding to the maximum frame average brightness from the upper limit luminance of the dark portion. , It is characterized in that the conversion of the inclination 1 is performed up to the value multiplied by a predetermined coefficient.

The video processing apparatus of the ninth invention is the video processing apparatus of any one of the first to eighth inventions, in which the video processing unit assigns a predetermined coefficient to the code value of the video signal corresponding to the maximum frame average brightness. It is characterized by converting from the multiplied value to the code value of the image corresponding to the maximum brightness of the content so as to have a constant inclination.

The video processing method of the tenth invention is a video processing that acquires content information and converts the video signal based on the brightness distribution of the content included in the acquired content information, and lifts and stretches the data in the dark part of the video signal. However, it is characterized in that the data in the bright part of the video signal is compressed.

According to the present invention, it is possible to reduce black crushing and improve image quality.

It is a block diagram which shows the structure of the BD player which concerns on 1st Embodiment of this invention. It is a figure for demonstrating the conversion process. It is a figure which shows before and after the conversion process. It is a figure which shows before and after the conversion process. It is a figure which shows before and after the conversion process. It is a block diagram which shows the structure of the AV receiver which concerns on 2nd Embodiment of this invention. It is a graph which shows an example of black crushing.

Hereinafter, embodiments of the present invention will be described.

(First Embodiment)
FIG. 1 is a block diagram showing a configuration of a BD (Blu-ray (registered trademark) Disc) player according to a first embodiment of the present invention. The BD player 1 (video processing device) includes a CPU 2, an operation unit 3, a playback unit 4, a video processing unit 5, an OSD processing unit 6, and a signal transmission unit 7. The CPU (Central Processing Unit) 2 (control unit) controls each unit constituting the BD player 1. The operation unit 3 is for receiving user operations, and is an operation button or a remote controller provided in the housing of the BD player 1.

The reproduction unit 4 (acquisition unit) reads, for example, a digital video signal from the BD 8 and reproduces it. The playback unit 4 acquires content information from the BD8 (medium) during playback. The content information includes the following information.
(1) Types of HDR standards.
(2) Type of EOTF (Electro-Optical Transfer Function).
(3) The minimum brightness of the scene or content, or the brightness equivalent thereto.
If none are present, the minimum brightness of the mastered monitor.
(4) Maximum brightness of the scene or content, or brightness equivalent to it.
If none are present, the maximum brightness of the mastered monitor.
(5) Maximum frame average brightness or brightness equivalent thereto.
Here, in (3) to (5), the information that can be acquired differs depending on the HDR standard and the content.

The video processing unit 5 performs video signal processing on the digital video signal reproduced by the playback unit 4. The video signal processing includes EOTF conversion, video signal conversion, and OETF (Optical-Electro Transfer Function) conversion.

The OSD (On Screen Display) processing unit 6 generates an OSD. The signal transmission unit 7 embeds the content information in the digital video signal and transmits the content information to the connected monitor (display device). Further, the signal transmission unit 7 acquires the information of the connected monitor.

In the present embodiment, the BD player 1 performs the following processing in order to improve the black crushing of the dark portion when the HDR signal is output to the monitor.
1. 1. Acquisition of content information 2. Conversion of video signal based on acquired information (brightness distribution of content included in content information) Here, the outline of conversion of video signal is "lifting and expanding data in dark areas, and is not often used based on content information. It is to compress the data in the bright part that is not. "

1. 1. The playback unit 4 acquires content information from the BD8 (medium). The video processing unit 5 acquires the above (1) to (5) from the acquired content information.

2. The video processing unit 5 converts the HDR signal according to the acquired information.

2-1. The video processing unit 5 sets the acquired brightness of (3) to the "minimum brightness of the content". Further, the video processing unit 5 sets the acquired brightness of (4) to the "maximum brightness of the content". Further, the video processing unit 5 sets the acquired brightness of (5) to the "maximum frame average brightness". Further, the image processing unit 5 sets the upper limit value of the brightness of the extended dark portion to the "upper limit brightness of the dark portion". That is, the video processing unit 5 sets the minimum brightness of the content, the maximum brightness of the content, and the maximum frame average brightness based on the content information acquired by the playback unit 4, and sets the upper limit value of the brightness of the extended dark portion. , Set to the upper limit brightness of dark areas.

2-2. The video processing unit 5 does not convert the video signal when the "minimum brightness of the content" is equal to or higher than the "upper limit brightness of the dark part". This is because it can be judged that there is no black crush because there is no dark part. When the "minimum brightness of the content" is smaller than the "upper limit brightness of the dark part", the video processing unit 5 performs the following 2-3 conversions (video signal conversion).

2-3. Since the conversion here is a conversion using a luminance value, the image processing unit 5 converts the code value of the video signal into a luminance value once according to EOTF, and then performs 2-3 conversions. After converting the luminance values of 2-3, the video processing unit 5 converts them into code values according to OETF.

FIG. 2 is a diagram for explaining the conversion process of 2-3. Each symbol is defined as follows.
Luminance value of video signal before L conversion
Luminance value of video signal after L'conversion
Bmax Upper limit brightness of dark areas The appropriate range of "upper limit brightness of dark areas" is "upper limit brightness of dark areas ≤ 10 cd / m ² ".
Minimum brightness of Cmin content
Maximum brightness of Cmax content
Fmax Maximum frame average brightness When "maximum frame average brightness = 0", the maximum value "400" recommended in the "BDA Authoring Guideline" is used instead of the "maximum frame average brightness".
Slope to a Bmax (real number)
The value of a is appropriately in the range of "1 ≤ a".
b Value that raises the brightness of dark areas (real number)
The appropriate value of b is in the range of "0 ≤ b".
c Coefficient (real number) for adjusting the upper limit of the range with a high appearance rate
The appropriate value of c is in the range of "1 ≤ c <1.2".
d Slope of the range with high appearance rate (real number)
A value close to "1" is appropriate for the value of d.
Luminance value (real number) obtained by converting e = d (cFmax --Bmax) + aBmax + b cFmax

The image processing unit 5 lifts and expands the dark part in order to improve the reproducibility of the dark part. Specifically, the video processing unit 5 adds a certain value b up to the “dark area upper limit brightness” and sets the coefficient a so as to increase with an inclination of 1 or more. The conversion formula is as follows.
L'= aL + b (L ≤ Bmax)

Further, the video processing unit 5 performs processing so that the gradation maintains the original gradation in the range having a high appearance rate. Specifically, the video processing unit 5 keeps the gradation from Bmax to the value cFmax obtained by multiplying the code value Fmax of the video signal corresponding to the "maximum frame average brightness" having a high appearance rate by the coefficient c. In order to maintain the original gradation, the conversion is performed with a slope of 1. The conversion formula is as follows.
L'= d (L --Bmax) + aBmax + b (Bmax <L ≤ cFmax)

The image processing unit 5 compresses a section of a bright portion having a low appearance rate. Specifically, the video processing unit converts the code value after cFmax to the code value of the video signal corresponding to the maximum brightness of the content so as to have a constant inclination. The conversion formula is as follows.
L'= (Cmax --e) / (Cmax --cFmax) * (L --cFmax) + e

Hereinafter, FIGS. 3 to 5 show an example in which the above means is used for a monitor that crushes a dark part up to 10 cd / m ^2. In this example, the following setting values are used.
Upper limit brightness of dark areas 10 nits
Code value of video signal corresponding to "upper limit brightness of dark part" Bmax 308
Minimum brightness of content 0.005 cd / m ²
Code value of video signal corresponding to "minimum brightness of content" Cmin 19
Maximum brightness of content 1977 cd / m ²
Code value of video signal corresponding to "maximum brightness of content" Cmax 842
Maximum frame average brightness 1112 cd / m ²
Code value of video signal corresponding to "maximum frame average brightness" Fmax 778
a 1
b 10
c 1
d 1

FIG. 3 (a) shows before conversion, and FIG. 3 (b) shows after conversion. 4 (a) and 4 (b) are enlarged dark areas of FIGS. 3 (a) and 3 (b), respectively. As shown in the figure, the brightness values other than the dark part are almost the same.

(Second Embodiment)
FIG. 6 is a block diagram showing a configuration of an AV receiver according to a second embodiment of the present invention. As shown in FIG. 6, the AV receiver 11 (video processing device) includes a CPU 12, an operation unit 13, a signal receiving unit 14, a video processing unit 15, an OSD processing unit 16, and a signal transmitting unit 17. Except for the signal receiving unit 14, the CPU 12, the operating unit 13, the video processing unit 15, the OSD processing unit 16, and the signal transmitting unit 17 relate to the processing for optimizing the dynamic range of the content, and the CPU 2 and the operating unit according to the first embodiment. 3. The same applies to the video processing unit 5, the OSD processing unit 6, and the signal transmission unit 7, so the description thereof will be omitted.

For example, a BD player is connected to the AV receiver 1. The signal receiving unit 14 receives the digital video signal output from the BD player. The CPU 2 causes the signal receiving unit 14 (acquisition unit) to acquire content information from the digital video signal.

As described above, in the present embodiment, the video processing units 5 and 15 extend the data in the dark part of the video signal by lifting it, and compress the data in the bright part of the video signal. As a result, it is possible to reduce black crushing and improve image quality.

Although the embodiments of the present invention have been described above, the embodiments to which the present invention can be applied are not limited to the above-described embodiments, and as illustrated below, appropriate as long as the gist of the present invention is not deviated. It is possible to make changes.

In the above-described embodiment, a BD player (source device) and an AV receiver (repeater device) are exemplified as the video processing device. Not limited to this, other video processing devices may be used.

The present invention can be suitably adopted in a video processing device that performs video signal processing on a video signal and a video processing method.

1 BD player (video processing device)
2 CPU (control unit)
3 Operation unit 4 Playback unit (acquisition unit)
5 Video processing unit 7 Signal transmission unit 11 AV receiver (video processing device)
12 CPU (control unit)
13 Operation unit 14 Signal reception unit (acquisition unit)
15 Video processing unit 17 Signal transmission unit

Claims (10)

The acquisition department that acquires content information and
A video processing unit that converts a video signal based on the luminance distribution of the content included in the content information acquired by the acquisition unit is provided.
The video processing unit is a video processing device characterized in that the data in the dark part of the video signal is lifted and expanded, and the data in the bright part of the video signal is compressed. The video processing unit
Based on the content information acquired by the acquisition unit, the minimum brightness of the content, the maximum brightness of the content, and the maximum frame average brightness are set.
The video processing apparatus according to claim 1, wherein the upper limit value of the brightness of the extended dark portion is set to the upper limit brightness of the dark portion. The video processing device according to claim 1 or 2, wherein the video processing unit does not convert a video signal when the minimum brightness of the content is equal to or higher than the upper limit brightness of the dark part. The video processing apparatus according to any one of claims 1 to 3, wherein the video processing unit converts a video signal when the minimum brightness of the content is smaller than the upper limit brightness of the dark part. Any one of claims 1 to 4, wherein the video processing unit converts the code value of the video signal into a luminance value according to EOTF (Electro-Optical Transfer Function), and then converts the video signal. The video processing device described in the section. The video processing apparatus according to claim 5, wherein the video processing unit converts the brightness value of the video signal into a code value according to OETF (Optical-Electro Transfer Function) after the video signal is converted. The video processing unit
Claims 1 to 6, wherein as a process of lifting and expanding the data of the dark part of the video signal, a constant value is added up to the upper limit brightness of the dark part and a coefficient is set so as to increase with a slope of 1 or more. The video processing apparatus according to any one of the following items. Claims 1 to 1, wherein the image processing unit performs conversion of substantially inclination 1 from the upper limit brightness of the dark portion to a value obtained by multiplying the code value of the video signal corresponding to the maximum frame average brightness by a predetermined coefficient. 7. The image processing apparatus according to any one of 7. The image processing unit converts the code value of the video signal corresponding to the maximum frame average brightness by multiplying it by a predetermined coefficient to the code value of the video corresponding to the maximum brightness of the content so as to have a constant inclination. The image processing apparatus according to any one of claims 1 to 8, wherein the image processing apparatus is used. Get content information,
As a video process that converts a video signal based on the brightness distribution of the content included in the acquired content information, it is characterized by lifting and expanding the data in the dark part of the video signal and compressing the data in the bright part of the video signal. Video processing method to do.

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