JP7110740B2 - Video switcher and switching method - Google Patents

Description

The present invention relates to a video switcher and switching method.

In recent years, with improvements in the performance of cameras and displays, it has become possible to shoot and display images with brightness that cannot be expressed by SDR (Standard Dynamic Range), which is the standard for brightness ranges up until now. Therefore, a standard called HDR (High Dynamic Range), which greatly expands the luminance range, has been introduced and is attracting attention. In the television broadcasting industry, HDR is to be supported in 4K practical broadcasting starting in December 2018 on BS (Broadcast Satellite)/CS (Communication Satellite).

In relation to the above, for example, Patent Literature 1 describes a technique for superimposing a plurality of images having different dynamic ranges, which is one of the image signal characteristics, and transmitting the superimposed images as a broadcast signal. Specifically, Patent Document 1 unifies the image signal characteristics including OETF (optical-electrical conversion characteristics) or EOTF (electrical-optical conversion characteristics) of those images. In the above description, OETF stands for Opto-Electrical Transfer Function, and EOTF stands for Electro-Optical Transfer Function.

In Patent Document 2, depending on whether the output destination of the video is HDR compatible, it is decided whether to output in HDR or SDR, and the video and graphics are converted from SDR to HDR according to the output format. , or there is a description of performing remapping processing from HDR to SDR.

JP 2016-111691 A Japanese Patent Publication No. 2015-174026

Starting in December 2018, not all content will be HDR all at once, and for the time being the existing SDR will also be supported. In other words, both standards will coexist for the time being. For example, in a variety program, studio images are recorded in HDR, but CM (Commercial Message) images and VTR (Video Tape Recorder) images inserted between studio images may be in SDR.

As a countermeasure against the coexistence of both standards, it is conceivable to fix the video signal characteristics to either HDR or SDR video signal characteristics within a certain period of time such as one program. A γ curve is used as a transfer function when converting light into an electric signal in an imaging device such as a camera or converting an electric signal into light in a display. However, since HDR and SDR have different curves, when HDR/SDR conversion is performed on HDR and SDR materials, errors may occur during conversion and inverse conversion processing, resulting in image quality degradation. . In particular, the base signal that forms the core of the program (for example, studio video in the case of a variety program) should not be degraded by HDR/SDR conversion.

On the other hand, it is conceivable to switch between HDR broadcasting and SDR broadcasting in units finer than program units (for example, in units of studio images, CMs, and VTRs). However, due to restrictions on the operation of not only the video switcher but also the entire broadcasting system including transmitters and receivers, it takes several seconds to switch between HDR and SDR in fine units as described above. Therefore, the broadcast screen becomes a black screen for the switching time. Therefore, a method of switching between HDR broadcasting and SDR broadcasting in units finer than program units is not realistic.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems. The purpose is to provide a technology that enables

The video switcher of the present invention comprises a first base signal conforming to a first standard having a first luminance range and a second base signal conforming to a second standard having a second luminance range wider than the first luminance range. , wherein the first base signal is converted into a first converted signal that is a signal of the second standard, and the second base signal is converted into a second converted signal that is a signal of the first standard. converting means for converting into a converted signal; receiving the first base signal and the second base signal; receiving the first converted signal and the second converted signal from the converting means; and distributing these signals. a switching means; a first processing section that combines either one of the first base signal and the second transformed signal with a superimposed signal to output a first combined signal as a combined result; and the first processing section. synthesizing means provided in parallel, comprising: a second processing unit for synthesizing either one of the second base signal and the first transformed signal with the superimposed signal and outputting a second synthesized signal as a synthesis result; , wherein the switching means selects one of the first synthesized signal and the second synthesized signal on a program-by-program basis.

The switching method of the present invention includes a first base signal conforming to a first standard having a first luminance range and a second base signal conforming to a second standard having a second luminance range wider than the first luminance range. is input and processed by a video switcher that converts the first base signal into a first conversion signal that is a signal of the second standard, and converts the second base signal into a second conversion signal that is a signal of the first standard. inputting said first base signal and said second base signal; inputting said first transformed signal and said second transformed signal; dividing these signals; a first process of synthesizing one of the transformed signals and the superimposed signal to output a first synthesized signal as a synthesis result; and one of the second base signal and the first transformed signal and the superimposed signal. and a second processing unit for synthesizing and outputting a second synthesized signal as a synthesized result, and selecting either the first synthesized signal or the second synthesized signal for each program. It is characterized by

According to the present invention, even when standards with different luminance ranges coexist, it is possible to perform broadcasting without adversely affecting the operation of the system and suppressing image quality deterioration of video.

1 is a block diagram showing a configuration example of a video switcher according to a first embodiment of the present invention; FIG. FIG. 7 is a block diagram showing a configuration example of a video switcher according to a second embodiment of the present invention; FIG. 3 is a block diagram showing a configuration example of a synthesizing unit shown in FIG. 2; FIG. FIG. 2 shows an operation example of the video switcher shown in FIG. 2 when BASE is input in SDR and the result of synthesis with SUPER is output in SDR. FIG. 2 shows an operation example of the video switcher shown in FIG. 2 when BASE is input in HDR and the synthesized result with SUPER is output in HDR.

[First embodiment]
(Description of configuration)
FIG. 1 is a block diagram showing a configuration example of a video switcher 10 according to the first embodiment of the invention. The video switcher 10 inputs a first base signal conforming to a first standard having a first luminance range and a second base signal conforming to a second standard having a second luminance range wider than the first luminance range. process. It is assumed that one of the first base signal and the second base signal is input to the video switcher 10 . Also, the first base signal and the second base signal are generally video signals.

The video switcher 10 includes a converting section 12 (an example of converting means), a switching section 14 (an example of switching means), and a synthesizing section 16 (an example of synthesizing means).

The converter 12 converts the first base signal into a first converted signal that is a signal of the second standard, and converts the second base signal into a second converted signal that is a signal of the first standard.

The switching unit 14 receives the first base signal and the second base signal from the outside, that is, from a device other than the video switcher 10, receives the first conversion signal and the second conversion signal from the conversion unit 12, and converts these signals into are distributed to the transforming unit 12 or the synthesizing unit 16 .

The synthesizing unit 16 includes a first processing unit 20 and a second processing unit 22 .

The first processing unit 20 combines either one of the first base signal and the second transformed signal with the superimposed signal and outputs a first combined signal as a result of combining. The first combined signal is a signal conforming to the first standard. The superimposed signal is a signal superimposed on the first base signal and the second base signal, which are video signals. The superimposed signal is, for example, weather/earthquake information, broadcast station or sponsor logo mark information, or caption information such as breaking news.

The second processing unit 22 combines either one of the second base signal and the first converted signal with the superimposed signal and outputs a second combined signal as a result of combining. The second combined signal is a signal conforming to the second standard. The superimposed signal is a signal superimposed on the first base signal and the second base signal, which are video signals. The superimposed signal is, for example, weather/earthquake information, broadcast station or sponsor logo mark information, or caption information such as breaking news. The second processing section 22 is provided in parallel with the first processing section 20 . That is, each composition in the first processing section 20 and the second processing section 22 is executed simultaneously.

The first combined signal and the second combined signal are input to switching section 14 . The switching unit 14 selects either one of the first synthesized signal and the second synthesized signal based on, for example, a program broadcast control signal (not shown in FIG. 1), and outputs it as one synthesized signal. The program broadcast control signal is, for example, a signal that switches on a program-by-program basis.
(Description of operation)
The operation (switching method) of the video switcher 10 will be described below with reference to FIG.

The switching unit 14 receives the first base signal and the second base signal from the outside, the switching unit 14 receives the first conversion signal and the second conversion signal from the conversion unit 12, and converts these signals to the conversion unit. 12 or synthesis unit 16 . For example, when a first base signal is input to the switching unit 14 as a base signal from the outside, the switching unit 14 outputs the first base signal to the conversion unit 12 and the first processing unit 20, and outputs the first base signal to the conversion unit 12 and the first processing unit 20. to output the first conversion signal.

Further, when the second base signal is input to the switching unit 14 as the base signal from the outside, the switching unit 14 outputs the second base signal to the conversion unit 12 and the second processing unit 22, and the first processing unit 20 to output the second conversion signal.

The first processing unit 20 combines either one of the first base signal and the second transformed signal with the superimposed signal. The second processing unit 22 combines either one of the second base signal and the first converted signal with the superimposed signal.

For example, when a first base signal is input from the outside to the switching section 14 as a base signal, the first processing section 20 combines the first base signal and the superimposed signal to output a first combined signal. Also, in this case, the second processing unit 22 combines the first converted signal and the superimposed signal and outputs the first combined signal.

On the other hand, when the second base signal is input to the switching section 14 as the base signal from the outside, the second processing section 22 combines the second base signal and the superimposed signal and outputs the second combined signal. Also, in this case, the first processing unit 20 combines the second converted signal and the superimposed signal to output the first combined signal.

The first combined signal and the second combined signal are input to switching section 14 . The switching unit 14 selects either one of the first synthesized signal and the second synthesized signal based on, for example, a program broadcast control signal (not shown in FIG. 1), and outputs it as one synthesized signal. The program broadcast control signal is, for example, a signal that switches on a program-by-program basis.
(Explanation of effect)
In the first embodiment described above, the synthesis process of synthesizing a superimposed signal without converting the base signal of each standard, and the superimposing process after converting the standard of the base signal into the other standard are superimposed. Signal and synthesis processing are always executed in parallel. The other is the second standard relative to the first standard or the first standard relative to the second standard. One of the two combined signals (first combined signal and second combined signal) generated in parallel is selected by the switching unit 14 and output as one combined signal.

In the above processing, the switching of the base signal that is the input and the switching of the two synthesized signals that are created in parallel are performed by the switching control of the switching section 14 . The above-described switching control is nothing more than simple switching of connections, and is executed in an extremely short period of time.

Furthermore, the luminance range of a certain program often corresponds to the luminance range of the main broadcast portion (main part) of the program. Whether or not to convert the base signal in the first embodiment described above is determined according to the input. In other words, the majority of the program remains unchanged without being converted. Therefore, image quality deterioration due to HDR/SDR conversion is limited.

In other words, according to the first embodiment, even when standards with different luminance ranges are mixed, it is possible to perform broadcasting without adversely affecting the operation of the system and suppressing image quality deterioration of images.

For example, the first standard is SDR and the second standard is HDR.
[Second embodiment]
(Description of configuration)
FIG. 2 is a block diagram showing a configuration example of the video switcher 100 according to the second embodiment of the invention. In this embodiment, the first standard is SDR and the second standard is HDR. Also, hereinafter, the "base signal" and "superimposed signal" in the first embodiment are represented by "BASE" and "SUPER", respectively. BASE includes an SDR video signal (BASE (SDR)) and an HDR video signal (BASE (HDR)).

The video switcher 100 includes a cross converter 102 (corresponding to the conversion unit 12 in FIG. 1), a matrix switcher 104 (corresponding to the switching unit 14 in FIG. 1), a synthesizing unit 106 (corresponding to the synthesizing unit 16 in FIG. 1), Prepare.

Cross converter 102 includes HDR/SDR converter 120 and SDR/HDR converter 122 . HDR/SDR converter 120 converts HDR to SDR. The SDR/HDR converter 122 converts SDR into HDR.

The matrix switcher 104 indicates a device that uses a matrix switch and is mainly used for switching or distributing electrical signals. The matrix switcher 104 has n (n is a positive integer) input terminals IN1 to INn (not shown in FIG. 2/arrows from above) for inputting a video signal (video material) from the outside, and an external video signal. It has m (m is a positive integer) output terminals OUT1 to OUTm (horizontal lines in FIG. 2) for outputting signals (video materials). That is, the matrix switcher 104 can select any point in the INPUT (vertical)×OUTPUT (horizontal) matrix. The matrix switcher 104 can select either one of the n external inputs or a reentry input from inside the video switcher 100 . The reentry input is, for example, the output of the cross-converter 102 (that is, each HDR/SDR-converted material). Also, output terminals OUT1 to OUTm output the outputs of synthesizing section 106 (for example, PGM (SDR) or PGM (HDR), which will be described later).

Note that n is a sufficiently large number in a general video switcher. For example, matrix switcher 104 is a matrix switcher compatible with 12G-SDI (Serial Digital Interface). Of course, the signal specification of matrix switcher 104 is not limited to the above.

Synthesizing section 106 synthesizes each BASE and SUPER distributed by matrix switcher 104 .

FIG. 3 is a block diagram showing a configuration example of combining section 106 shown in FIG. The synthesizing unit 106 includes a BASE processing system and a SUPER processing system, and synthesizes SUPER for each BASE.

The BASE processing system has two processing systems. Specifically, the BASE processing system includes an SDR processing unit 200 of the SDR system (corresponding to the first processing unit 20 in FIG. 1) and an HDR processing unit 210 of the HDR system (corresponding to the second processing unit 22 in FIG. 1). is. The SDR processing unit 200 receives BASE (SDR), and the HDR processing unit 210 receives BASE (HDR).

This embodiment has two synthesizing processing systems, that is, an HDR system and an SDR system, and the synthesizing processes of BASE and SUPER are executed in parallel in the respective systems. Specifically, in this embodiment, in order to eliminate the need to switch processing depending on whether the input material is HDR or SDR, the cross converter 102 converts HDR to SDR and SDR to HDR regardless of the input material. Always running conversions. Synthesizing section 106 always outputs PGM (SDR) and PGM (HDR) as a result of synthesizing HDR and SDR (synthesizing each BASE and SUPER). PGM refers to an on-air signal. PGM(SDR) corresponds to the "first synthesized signal" in FIG. 1, and PGM(HDR) corresponds to the "second synthesized signal" in FIG.

The SDR processing unit 200 includes an MK unit 202 , a DSK unit 204 and an L-character synthesizing unit 206 . Note that MK is an abbreviation for Mixer/Keyer, and DSK is an abbreviation for Down Stream Keyer.

The MK unit 202 executes MK. MK is one of the basic synthesizing functions for synthesizing two or more images in television image editing technology, and is used for superimposing images, providing superimposition, and the like.

The DSK unit 204 executes DSK. DSK is a downstream synthesizing function when synthesizing and mixing video on the upstream side (upstream) and performing key synthesis on the result further downstream (downstream). In general, logos, texts, and the like are synthesized by DSK. With this function, it is possible to display a logo or a bulletin super display.

The L-character synthesis unit 206 performs L-character synthesis. L-character composition is a kind of DVE (Digital Video Effect) that enlarges, reduces, transforms, and processes video, and refers to processing that realizes a layout for L-character broadcasting.

The MK unit 202, the DSK unit 204, and the L-character synthesizing unit 206 each receive a dedicated SUPER (SUPER for MK (SDR), SUPER for DSK (SDR), and SUPER for L-character synthesis (SDR)). The MK SUPER (SDR) and the DSK SUPER (SDR) include, for example, a FILL signal (video signal to be inserted) and/or a KEY signal (information about the position in BASE where the FILL signal is inserted). L-shaped synthesis SUPER (SDR) includes, for example, a background signal (sometimes called BGD).

SUPER (SDR) for MK, SUPER (SDR) for DSK, and SUPER for L-character synthesis are all input in SDR format. Therefore, in the SDR processing unit 200, SUPER (SDR) is directly combined with BASE (SDR). On the other hand, in the HDR processing unit 210, SUPER (HDR) converted from SDR to HDR in the SUPER processing unit 220 and BASE (HDR) are synthesized.

HDR processing unit 210 includes MK unit 212 , DSK unit 214 , and L-character synthesis unit 216 . The functions of the MK unit 212, the DSK unit 214, and the L-character synthesizing unit 216 are the same as those of the MK unit 202, the DSK unit 204, and the L-character synthesizing unit 206 of the SDR processing unit 200, except for the difference in standards between SDR and HDR. are identical to each other.

In addition, in the SDR processing unit 200 and the HDR processing unit 210 in FIG. 3, processing is performed in the order of MK→DSK→L-character synthesis. In a general video switcher, MK comes in the first stage, but this is not the only option and the order may be random. In addition, each process (MK/DSK/L character) may not be one, but may be plural.

Specifically, the SUPER processing system is the SUPER processing unit 220 . One SUPER processing unit 220 is provided in the synthesizing unit 106 and is shared by the SDR processing unit 200 and the HDR processing unit 210 . The SUPER processing unit 220 includes an MK conversion unit 222 , a DSK conversion unit 224 , and an L-character synthesis conversion unit 226 .

The conversion unit for MK 222 converts the input SUPER for MK (SDR) into HDR, and outputs the converted signal to the SUPER for MK (HDR) to the MK unit 212 .

The DSK conversion unit 224 converts the input DSK SUPER (SDR) into HDR, and outputs the converted signal to the DSK unit 214 as DSK SUPER (HDR).

The conversion unit 226 for L-character synthesis converts the input L-character synthesis SUPER (SDR) into HDR, and outputs the converted signal to the L-character synthesis unit 216 as L-character synthesis SUPER (HDR). .

Each SUPER is fixed to SDR at the start of 4K broadcasting in December 2018, but may change to HDR in the future.

The SDR/HDR conversion method in the SUPER processing unit 220 is, for example, the HLG (Hybrid Log Gamma) method defined in ARIB STD-B67 or Rec.BT.2100. BT.2100 considers SDR as γ=2 and allocates 100% of SDR to 50% of HLG. ARIB stands for Association of Radio Industries and Businesses.

However, when an HDR material and an SDR material are mixed, there is a problem that the SDR material looks dark at 50% of HLG. Therefore, this embodiment allocates 100% of SDR to 75% of HLG according to ARIB TR-B43.

The SDR/HDR conversion of ARIB TR-B43 is described below. There are two types of SDR/HDR conversion methods: a “scene reference type” and a “display reference type”. The “scene reference type” matches the color and gradation of the video signal mapped from the SDR camera video signal to the HDR with the color and gradation of the HDR camera video signal. The “scene reference type” is used, for example, when both SDR and HDR cameras are used during live production. "Display reference type" matches the color and gradation when a video signal mapped from SDR to HDR is displayed on an HDR display device to the color and gradation when an SDR video signal is displayed on an SDR display device. Let The “display reference type” is used, for example, when SDR-produced content is used in an HDR program.
(Description of operation)
FIG. 4 is a diagram for showing an operation example of the video switcher 100 when BASE is input in SDR and the result of synthesis with SUPER is output in SDR. In FIG. 4 , black circles indicate connection points in the matrix switcher 104 .

In this case, BASE (SDR), BASE (HDR) converted from SDR to HDR by cross converter 102 , and SUPER (SDR) are input to synthesizing section 106 .

The SDR processing unit 200 of the synthesizing unit 106 synthesizes “BASE (SDR)” and “SUPER (SDR)” to create “PGM (SDR)”. At the same time, the HDR processing unit 210 of the synthesizing unit 106 synthesizes “BASE (HDR)” and “SUPER (HDR) converted from SDR to HDR” to create “PGM (HDR)”.

When sending in SDR, "PGM (SDR)" is output from OUT1 of the matrix switcher 104. FIG.

FIG. 5 is a diagram illustrating an operation example of the video switcher 100 when BASE is input in HDR and the result of synthesis with SUPER is output in HDR. In FIG. 5 , black circles indicate connection points in the matrix switcher 104 .

In this case, BASE (HDR), BASE (SDR) converted from HDR to SDR by cross converter 102 , and SUPER (SDR) are input to synthesizing section 106 .

The HDR processing unit 210 of the synthesizing unit 106 synthesizes “BASE (HDR)” and “SUPER (HDR) converted from SDR to HDR” to create “PGM (HDR)”. At the same time, the SDR processing unit 200 of the synthesizing unit 106 synthesizes “BASE (SDR)” and “SUPER (SDR)” to create “PGM (SDR)”.

When outputting in HDR, "PGM (HDR)" is output from OUT1 of the matrix switcher 104. FIG.

That is, when the program is SDR-designated, "PGM (SDR)" is output from OUT1 of matrix switcher 104, and when the program is HDR-designated, "PGM (HDR)" is output from OUT1 of matrix switcher 104. be done.

BASE in PGM(SDR) remains SDR when the input is SDR, and becomes SDR converted from HDR when the input is HDR.

On the other hand, BASE in PGM (HDR) is HDR converted from SDR when the input is SDR, and remains HDR when the input is HDR.
(Explanation of effect)
The video switcher 100 according to the second embodiment described above has two synthesizing processing systems, and performs synthesizing processing with SUPER in parallel for each of the HDR system and the SDR system. Further, the video switcher 100 outputs "PGM (SDR)" from OUT1 of the matrix switcher 104 when transmitting in SDR, and outputs "PGM (HDR)" from OUT1 of the matrix switcher 104 when transmitting in HDR. be. That is, in video switcher 100, when the program is SDR-designated, "PGM (SDR)" is output from OUT1 of matrix switcher 104, and when the program is HDR-designated, "PGM (SDR)" is output from OUT1 of matrix switcher 104. HDR)” is output.

From the above, according to the second embodiment, as in the first embodiment, even if a plurality of standards with different luminance ranges are mixed, the operation of the system is not adversely affected, and Broadcasting can be performed while suppressing image quality deterioration of video.

In FIGS. 3 to 5, the output of the synthesizing unit 106 is only PGM (for on-air) in order to make the explanation clearer, but the output of the synthesizing unit 106 is not limited to this. . For example, combining section 106 can further output PVW (for prior confirmation). Further, the synthesizing unit 106 does not provide the final synthesizing result (MK+DSK+L-shaped synthesizing), but the result of each synthesizing unit (for example, only MK), or the result of an arbitrary combination of each synthesizing (for example, MK+DSK) (for on-air and/or pre-combining). for confirmation) can be output. Furthermore, the combiner 106 can output CLN (a signal on which no combination has been performed).

Furthermore, the synthesizing unit 106 may perform FADE processing (so-called fade-in/fade-out processing or cross-fade processing) on each BASE before synthesizing.

Although the present invention has been described using each embodiment, the technical scope of the present invention is not limited to the description of each embodiment. It is obvious to those skilled in the art that various modifications or improvements can be made to each of the above embodiments. Therefore, it is needless to say that the forms with such changes or improvements are also included in the technical scope of the present invention. Numerical values, names of components, and the like used in each of the embodiments described above are examples and can be changed as appropriate.

10 video switcher 12 conversion unit 14 switching unit 16 synthesis unit 20 first processing unit 22 second processing unit 100 video switcher 102 cross converter 104 matrix switcher 106 synthesis unit 120 HDR/SDR conversion unit 122 SDR/HDR conversion unit 200 SDR processing unit 202 MK unit 204 DSK unit 206 L-character synthesis unit 210 HDR processing unit 212 MK unit 214 DSK unit 216 L-character synthesis unit 220 SUPER processing unit 222 Conversion unit for MK 224 Conversion unit for DSK 226 Conversion unit for L-character synthesis

Claims (4)

An image processed by inputting a first base signal conforming to a first standard having a first luminance range and a second base signal conforming to a second standard having a second luminance range wider than the first luminance range. a switcher,
conversion means for converting the first base signal into a first conversion signal that is a signal of the second standard, and converting the second base signal into a second conversion signal that is a signal of the first standard;
switching means for inputting the first base signal and the second base signal, inputting the first conversion signal and the second conversion signal from the conversion means, and distributing these signals;
a first processing unit for synthesizing either one of the first base signal and the second transformed signal and a superimposed signal to output a first synthesized signal as a result of synthesis, provided in parallel with the first processing unit and a combining means comprising a second processing unit that combines either one of the second base signal and the first transformed signal with the superimposed signal and outputs a second combined signal as a combined result,
A video switcher, wherein the switching means selects either one of the first synthesized signal and the second synthesized signal on a program-by-program basis. 2. The image according to claim 1, wherein said switching means selects either one of said first synthesized signal and said second synthesized signal based on a program broadcast control signal which is a signal that switches on a program-by-program basis. Switcher. 3. The video switcher according to claim 1, wherein said first standard is SDR (Standard Dynamic Range) and said second standard is HDR (High Dynamic Range). An image processed by inputting a first base signal conforming to a first standard having a first luminance range and a second base signal conforming to a second standard having a second luminance range wider than the first luminance range. by the switcher
converting the first base signal into a first converted signal that is a signal of the second standard, converting the second base signal into a second converted signal that is a signal of the first standard;
inputting said first base signal and said second base signal, inputting said first transformed signal and said second transformed signal, dividing these signals;
a first process of synthesizing either one of the first base signal and the second transformed signal with a superimposed signal to output a first synthesized signal as a synthesis result; and the second base signal and the first transformed signal. and a second processing unit for synthesizing one of the superimposed signals and outputting a second synthesized signal as a synthesis result,
A switching method, wherein either one of the first synthesized signal and the second synthesized signal is selected on a program-by-program basis.

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