JP2020074613A - Camera system, video processing method, program, video system, and video converter - Google Patents

Abstract

To solve various problems that occur when simultaneously generating a plurality of videos different in dynamic ranges, such as HDR video and SDR video, from pixel signals captured by an imaging part.SOLUTION: A video system includes a camera system and a video converter. The camera system has: an imaging part for obtaining pixel signals by capturing a subject; and a first processing circuit for generating respectively two video signals from the pixel signals while applying different adjustments for each other, and transmitting the transmission information where information about the adjustment of each video signal is added to one video signal. The video converter includes a second processing circuit for extracting the information about the adjustment of each video signal from the transmission information, generating a restoration pixel signal by performing reverse conversion of one video signal included in the transmission information, on the basis of the information about the adjustments, and generating a video signal corresponding to the other video signal by adding the adjustment for the other video signal to this restored pixel signal.SELECTED DRAWING: Figure 1

Description

  The present technology relates to a camera system, a video processing method, a program, a video system, and a video converter that process a plurality of types of video signals whose levels, colors, etc. are adjusted under different conditions.

  HDR (High Dynamic Range) imaging is capable of expressing images with a wide dynamic range, and cannot be expressed with SDR (Standard Dynamic Range) image signals that have a standard dynamic range that can be displayed on a normal monitor. It is possible to express high brightness and express colors with high brightness.

  Patent Document 1 discloses a method of encoding HDR video and LDR video together.

Japanese Patent Publication No. 2015-506623

  The present technology is intended to solve various problems in processing a plurality of video signals each adjusted under different conditions.

In order to solve the above problems, a video system according to an embodiment of the present technology is
It has a camera system and a video converter,
The camera system is
A second image different from the first image adjustment parameter is generated based on the first image adjustment parameter from the pixel signal generated by the image pickup unit that picks up an image of a subject and obtains a pixel signal. A second video signal is generated based on the adjustment parameter, and transmission information in which the first adjustment parameter and the second adjustment parameter are added to the second video signal is transmitted via a first transmission path. 1 processing circuit,
The video converter is
Receiving the transmission information via the first transmission path,
Based on the second image adjustment parameter included in the transmission information, the second video signal included in the transmission information is inversely converted to generate a restored pixel signal, and the first pixel included in the transmission information is converted. A second processing circuit that performs an adjustment process corresponding to the first video signal on the restored signal based on one adjustment parameter to generate an output video signal corresponding to the first video signal. ..

  In the video system according to an aspect of the present technology, the first image adjustment parameter and the second image adjustment parameter include image adjustment parameters relating to levels of the first video signal and the second video signal, The dynamic range of the first video signal is narrower than the dynamic range of the second video signal.

  In the video system according to one aspect of the present technology, the first image adjustment parameter and the second image adjustment parameter include image adjustment parameters relating to colors of the first video signal and the second video signal. May be

  In the video system according to the aspect of the present technology, the first video signal may be SDR (Standard Dynamic Range) video and the second video signal may be HDR (High Dynamic Range) video. ..

In one aspect of the present technology, only the second video signal of the first video signal and the second video signal is transmitted from the camera system to the video converter through a second transmission path. The first processing circuit and the second processing circuit are configured to
The second processing circuit is configured to transmit an output video signal corresponding to the first video signal to a display via a third transmission line different from the second transmission line. Good.

Another form of video processing method according to the present technology is
With the camera system,
A first processing circuit generates a first video signal based on a first image adjustment parameter from the pixel signal generated by an image pickup unit that picks up an image of a subject and obtains a pixel signal. A second video signal based on a second image adjustment parameter different from the above, and the first transmission of transmission information in which the first adjustment parameter and the second adjustment parameter are added to the second video signal. Transmission through the road,
With a video converter,
Receiving the transmission information via the first transmission path,
The second processing circuit inversely transforms the second video signal included in the transmission information to generate a restored pixel signal based on the second image adjustment parameter included in the transmission information, and the transmission is performed. An adjustment process corresponding to the first video signal is performed on the restored signal based on the first adjustment parameter included in the information, and an output video signal corresponding to the first video signal is generated.

Another form of program according to the present technology is
With the camera system,
A second image different from the first image adjustment parameter is generated based on the first image adjustment parameter from the pixel signal generated by the image pickup unit that picks up an image of a subject and obtains a pixel signal. A second video signal is generated based on the adjustment parameter, and transmission information in which the first adjustment parameter and the second adjustment parameter are added to the second video signal is transmitted via a first transmission path. 1 processing circuit,
With a video converter,
Receiving the transmission information via the first transmission path,
Based on the second image adjustment parameter included in the transmission information, the second video signal included in the transmission information is inversely converted to generate a restored pixel signal, and the first pixel included in the transmission information is converted. A computer as a second processing circuit that performs an adjustment process corresponding to the first video signal on the restored signal based on one adjustment parameter, and generates an output video signal corresponding to the first video signal. The program to run.

Another form of camera system according to the present technology is
A second image different from the first image adjustment parameter is generated based on the first image adjustment parameter from the pixel signal generated by the image pickup unit that picks up an image of a subject and obtains a pixel signal. A second video signal is generated based on the adjustment parameter, and transmission information in which the first adjustment parameter and the second adjustment parameter are added to the second video signal is transmitted via a first transmission path. 1 processing circuit.

Another form of video converter according to the present technology is
A second image different from the first image adjustment parameter is generated based on the first image adjustment parameter from the pixel signal generated by the image pickup unit that picks up an image of a subject and obtains a pixel signal. A camera that generates a second video signal based on an adjustment parameter and transmits transmission information obtained by adding the first adjustment parameter and the second adjustment parameter to the second video signal via a first transmission path. Based on the second image adjustment parameter included in the transmission information transmitted from the system, the second video signal included in the transmission information is inversely converted to generate a restored pixel signal, and An adjustment process corresponding to the first video signal is performed on the restored signal based on the included first adjustment parameter, and an output process corresponding to the first video signal is performed. It comprises a second processing circuit for generating a video signal.

  As described above, according to the present technology, it is possible to solve various problems when processing a plurality of video signals each adjusted under different conditions.

It is a block diagram showing the whole video system 1 composition of a 1st embodiment concerning this art. It is a block diagram which shows the functional structure of the HDR process part 122 and SDR process part 123 of the camera control unit 12 in the video system 1 of 1st Embodiment. It is a block diagram which shows the functional structure of the reverse HDR process part 201 and the SDR process part 202 of the video converter 20 in the video system 1 of 1st Embodiment. It is a block diagram showing the whole video system 1A composition of a 2nd embodiment concerning this art. It is a block diagram which shows the functional structure of the reverse HDR process part 125 and the SDR process part 123 of the camera control unit 12 in the video system 1A of 2nd Embodiment.

Hereinafter, embodiments according to the present technology will be described.
<First Embodiment>
[Video system configuration]
FIG. 1 is a block diagram showing the overall configuration of a video system 1 according to the first embodiment of the present technology.
As shown in the figure, the video system 1 includes a camera system 10 and a video converter 20. The camera system 10 and the video converter 20 are connected via a main line transmission line 30.

[Configuration of camera system 10]
The camera system 10 includes an imaging device 11 and a camera control unit 12. The imaging device 11 and the camera control unit 12 are connected via a camera cable 13 such as an optical fiber.

  The image pickup apparatus 11 has an optical system 110 having a lens group for image pickup, an image pickup element 111, a preprocessor 112, a transmission unit 113, and a CPU 114.

  The image sensor 111 is an image sensor such as a CMOS (Complementary Metal-Oxide-Semiconductor) element or a CCD (Charge-Coupled Device), and converts light captured through an optical system (not shown) into an electrical pixel signal corresponding to the light intensity. Convert.

  In addition, in the configuration of the video system 1 of the present technology, the “imaging unit” corresponds to the imaging device 11 described above.

  The preprocessor 112 performs defect correction on the pixel signals obtained by the image sensor 111, signal correction processing such as lens aberration correction, and the like.

  The transmission unit 113 performs a process of transmitting the pixel signal output from the preprocessor 112 to the camera control unit 12 via the camera cable 13. That is, the pixel signal transmitted to the camera control unit 12 by the transmission unit 113 is a RAW image signal that has not been subjected to gain or dynamic range processing, debayer processing, gamma signal processing, or the like.

  The CPU 114 is a controller that controls each unit of the imaging device 11 and communicates with the CPU 124 of the camera control unit 12 through the camera cable 13.

  On the other hand, the camera control unit 12 includes a transmission unit 121, an HDR process unit 122, an SDR process unit 123, and a CPU 124.

  The transmission unit 121 is configured by a communication circuit or the like that performs wired or wireless communication, receives the pixel signal transmitted from the imaging device 11 through the camera cable 13 (first transmission path), and receives the HDR process unit 122 and the SDR process unit. To 123.

  The HDR process unit 122 performs a process of generating an HDR video while performing various adjustments on the pixel signal supplied from the transmission unit 121 based on the parameter information for HDR adjustment. The HDR video generated by the HDR process unit 122 is transmitted to the video converter 20 through the main transmission line 30 with the parameter information for HDR adjustment and the parameter information for SDR adjustment added. As a method of adding the adjustment parameter information, the CPU 124 may perform a process of multiplexing the adjustment parameter information with the HDR video stream, and the HDR is obtained as a metadata file associated with the HDR video stream. The video may be output to the main transmission line 30 separately from the video. The main line transmission line 30 may be configured as a single transmission line, or the HDR video stream may be transmitted through a dedicated transmission line having a transmission band larger than that of the general-purpose transmission line and the adjustment parameter information may be transmitted through the dedicated transmission line. It may be configured as a plurality of transmission lines, such as a general-purpose transmission line having a smaller transmission band.

  The SDR process unit 123 performs a process of generating an SDR video while applying various adjustments to the pixel signal supplied from the transmission unit 121 based on the SDR adjustment parameter information. The SDR video generated by the SDR process unit 123 is transmitted to the display 41 of the operation device 40 of the video producer through the output transmission path 35, for example. The output transmission lines of the HDR process unit 121 and the SDR process unit 123 can be different transmission lines. For example, the SDR video is displayed on the display 41 of the operation device 40 of the video producer via the output transmission line 35 (third transmission line) independent of the main line transmission line 30 (second transmission line).

  The HDR process unit 122, the SDR process unit 123, and the CPU 124 are configured by one or a plurality of integrated circuits, and correspond to the first processing circuit in the configuration of the present technology.

  The CPU 124 is a controller that controls each unit in the camera control unit 12. The CPU 124 can communicate with the HDR process unit 122 and the SDR process unit 123 and control the selection of adjustment content to be added to the image signal in each process.

  Further, the CPU 124 adds the parameter information used for adjusting the pixel signal in the HDR process by the HDR process unit 122 and the SDR process by the SDR process unit 123 to the HDR video generated by the HDR process unit 122. , Control is performed so as to transmit to the video converter 20 through the main line transmission path 30.

  The CPU 124 can communicate with the operation device 40 connected via a communication path 50 such as a LAN (Local Area Network). The operation device 40 includes a display 41, an operation input unit 42, and a control unit 43. The operation device 40 may be composed of, for example, an information processing device such as a personal computer or the like, or may be composed of a dedicated control panel or the like made for camera control. The operation input unit 42 may include, for example, operation keys, a mouse, a trackball, a dial, a lever, a touch sensor panel, a remote controller, and the like. The control unit 43 of the operation device 40 includes a circuit such as a CPU, receives various control commands and setting information from a creator such as a VE (Video Engineer), and communicates with the CPU 124 of the camera control unit 12 via the communication path 50. Communicate between.

[Configurations of HDR process unit 122 and SDR process unit 123]
FIG. 2 is a block diagram showing a functional configuration of the HDR process unit 122 and the SDR process unit 123 of the camera control unit 12.

  The HDR process unit 122 includes an HDR gain adjustment unit 221, a matrix processing unit 223, a black level correction unit 225, a detail processing unit 227, an OETF unit 228, and a formatter 229.

  The HDR gain adjustment unit 221 performs control of RGB gain for white balance adjustment, in addition to control of master gain.

  The matrix processing unit 223 uses the color gamut information (HDR-Color Gamut), which is a part of the HDR adjustment parameter information and is information about the color of the HDR video, to determine the pixel signal that has passed through the HDR gain adjustment unit 221. To obtain color image data.

  The black level correction unit 225 corrects the black level of the color image data based on the information (HDR-Black) for black level correction, which is a part of the parameter information for HDR adjustment.

The detail processing unit 227 processes details of color image data.
The OETF unit 228 performs OETF (Optical-Electro Transfer Function) on color image data based on OETF information that is a part of HDR adjustment parameter information that is information about gamma for HDR transmission. Gamma signal processing of.
The formatter 229 converts the color image data that has passed through the OETF section 228 into the HDR video transmission format.

  On the other hand, the SDR process unit 123 includes a resolution conversion unit 230, an SDR gain adjustment unit 231, a matrix processing unit 233, a black level correction unit 235, a knee detail processing unit 237, a gamma processing unit 238, and a formatter 239.

  The resolution conversion unit 230 converts the resolution (for example, 4K resolution) of the pixel signal transmitted from the imaging device 11 into the HD resolution.

The SDR gain adjusting unit 231 controls the master gain based on the relative gain (Relative-Gain) which is a part of the parameter information for SDR adjustment and is the parameter information regarding the levels of the SDR video and the HDR video. , RGB gain control for white balance adjustment is performed.
The relative gain is a parameter indicating a ratio of a gain for a pixel signal in the HDR process and a gain for a pixel signal in the SDR process in order to adjust the contrast ratio between the HDR video and the SDR video. .. For example, the relative range defines how many times the dynamic range of HDR video is set with respect to the dynamic range of SDR video. With this relative range, the ratio of the master gain on the SDR process side to the master gain on the HDR process side can be set to an arbitrary ratio such as 1, 1/2. If the ratio of the master gain on the HDR process side to the master gain on the SDR process side is set in this way, the dynamic range of HDR video having a correlation with the dynamic range of SDR video can be obtained.

  More specifically, the upper limit of the dynamic range of SDR video is given by the reference white (Diffuse-White) selected by the creator. In the video system 1 of the present embodiment, by selecting the reference white (Diffuse-White) of the SDR video, the upper limit reference of the dynamic range of the HDR video (of the HDR video is based on the correlation based on the relative range). A reference white (Diffuse-White) is also determined.

  The relative range should be appropriately selected depending on the shooting environment such as daytime, nighttime, indoors, outdoors, in the studio, fine weather, and rainy weather. Therefore, a plurality of types of relative ranges associated with various shooting environments are prepared. As a method of preparing a plurality of types of relative ranges associated with the shooting environment, a method of comparing the apparent brightness of the SDR video and the HDR video simultaneously output from the camera control unit 12 with human eyes can be considered. .. Each time the value of the relative range is changed, the SDR video and the HDR video are compared, and the relative range in which the apparent brightness of the SDR video and the HDR video are close to each other may be determined as the optimal relative range for the shooting environment.

  Note that the relative gain may be information for performing white balance processing or contrast processing for SDR video, and may be, for example, a value other than the numerical value of the ratio to the gain of the HDR signal, such as a gain value for RAW data that is a sensor output value. Information is also acceptable.

  The luminance dynamic range of HDR video is wider than the luminance dynamic range of SDR video. As an example, if the luminance dynamic range of the SDR video is 0 to 100%, the luminance dynamic range of the HDR video is, for example, 100% to 1300% or 100% to 10000%. The brightness range of the output of the imaging device 10 is 0 to 600%.

  The matrix processing unit 233, based on the color gamut information (SDR-Color Gamut) that is a part of the SDR adjustment parameter information and is information about the color of the SDR video, the pixel signal that has passed through the SDR gain adjustment unit 231. To obtain color image data.

  The black level correction unit 235 corrects the black level of the color image data based on the black level correction information (SDR-Black) that is a part of the SDR adjustment parameter information.

  The knee detail processing unit 237 performs knee correction on color image data based on information (KNEE) regarding knee correction, which is a part of parameter information for SDR adjustment, and also performs detail processing.

  The gamma processing unit 238, based on the dynamic range compression information (SDR-D-Range-Gamma) that is part of the SDR adjustment parameter information, sets the gamma for the dynamic range set in the SDR gain adjustment unit 231. Signal processing is performed, and at the same time, gamma signal processing for display is performed.

  The formatter 239 converts the color image data into the SDR video transmission format.

  The parameter information is set by a creator such as a VE (Video Engineer) operating an operating device connected to the camera control unit 12 via a communication path such as a LAN (Local Area Network).

[Structure of video converter 20]
The video converter 20 has an inverse HDR process unit 201, an SDR process unit 202, and a CPU 203.

  The CPU 203 extracts the parameter information for HDR adjustment and the parameter information for SDR adjustment from the HDR video with parameter information received through the main transmission line 30, and supplies the inverse HDR process unit 201 with the parameter information for HDR adjustment. Further, the CPU 203 provides the SDR adjustment parameter information to the SDR process unit 202.

  The inverse HDR process unit 201 performs the inverse HDR process on the HDR video received through the main transmission line 30 using the parameter information for HDR adjustment. That is, the inverse HDR process unit 201 removes the adjustment component from the HDR video and generates the restored pixel signal.

  The SDR process unit 202 generates an output video signal corresponding to the SDR video generated by the camera control unit 12 from the restored pixel signal obtained by the inverse HDR process unit 201 using the parameter information for SDR adjustment. To do.

  The reverse HDR process unit 201, the SDR process unit 202, and the CPU 203 are configured by one or a plurality of integrated circuits, and correspond to the second processing circuit in the configuration of the present technology.

[Configurations of Reverse HDR Process Unit 201 and SDR Process Unit 202]
FIG. 3 is a block diagram showing a functional configuration of the inverse HDR process unit 201 and the SDR process unit 202 in the video converter 20.

  The inverse HDR process unit 201 has a deformatter 241, an inverse OETF unit 242, and a black level correction removing unit 243.

  The deformatter 241 releases the HDR video transmission format.

  The inverse OETF unit 242 removes the OETF gamma applied to the HDR video based on the information (the type of OETF) about the HDR transmission gamma that is a part of the HDR adjustment parameter information.

  The black level correction removing unit 243 cancels the black level correction applied to the HDR video based on the black level correction information (HDR-Black) which is a part of the parameter information for HDR adjustment. I do.

  The configuration of the SDR process unit 202 of the video converter 20 is the same as the configuration of the SDR process unit 202 of the camera control unit 12. That is, the SDR process unit 202 of the video converter 20 includes a resolution conversion unit 230, an SDR gain adjustment unit 231, a matrix processing unit 233, a black level correction unit 235, a knee detail processing unit 237, a gamma processing unit 238, and a formatter 239. ..

  Here, of the HDR video and the SDR video generated by the camera system 10, the HDR video is transmitted to the video converter 20 through the main line transmission line 30. The SDR video confirms the visual state of the video creator. This is because only the HDR video is transmitted to the main transmission line 30. In addition, if the HDR video and the SDR video are simultaneously transmitted through the main line transmission line 30, the transmission band of the main line transmission line 30 may be compressed. Under such circumstances, it is desirable that only the HDR video is transmitted to the main transmission line 30. Therefore, in the camera system 10, for example, the output transmission line 35 of the SDR process unit 123 outputs the SDR video, and the display 41 of the operation device 40 displays the SDR video for visually confirming the captured video. The SDR video may not be output to 30.

  There is also a demand for multiple creators to simultaneously check the expression of the created video in different places. It is possible to check the HDR video received through the main line transmission line 30 on a monitor that can display the HDR video, but the selection of expressions such as brightness and color of the video is adjusted at the time of shooting according to the traditional method. There are many people who want to use SDR video as a standard. Also, even if the resolution of HDR video is changed to the resolution of SDR video by down-conversion and displayed on the monitor, the visual expression is different from that of HDR video due to the difference in the dynamic range between HDR video and SDR video. turn into. Under such circumstances, the video system 1 of this embodiment is proposed.

  In addition, even if HDR video and SDR video are required as the main line images at the same time, it is uneconomical to treat both videos equally in the entire system configuration because it requires two systems completely, which is uneconomical. , HDR video can be handled and converted to SDR at the final stage, so that both videos can be handled as main line images.

[Operation of this video system 1]
Next, in the video system 1, of the HDR video and the SDR video generated by the camera system 10, the HDR video is transmitted to the video converter 20 through the main transmission line 30, and the video converter 20 converts the HDR video into the camera system 10. The operation in the case of generating the output video signal corresponding to the SDR video generated in 1. will be described.

(Operation of camera system 10)
The pixel signal obtained by the imaging device 11 is transmitted to the camera control unit 12 through the camera cable 13 by the transmission unit 113. In the camera control unit 12, the pixel signal received by the transmission unit 121 is supplied to the HDR process unit 122 and the SDR process unit 123.

  The HDR process unit 122 makes various adjustments based on the HDR adjustment parameter information provided by the CPU 124 while the HDR video is generated from the pixel signals. Similarly, the SDR process unit 123 also performs various adjustments based on the SDR adjustment parameter information provided by the CPU 124 while the SDR video is generated from the pixel signals.

  The CPU 124 adds the HDR adjustment parameter information used by the HDR process unit 122 to adjust the HDR video and the SDR adjustment parameter information used by the SDR process unit 123 to adjust the SDR video to the HDR video and transmits the main line. Control is performed to transmit to the video converter 20 through the path 30.

  On the other hand, the SDR video generated by the SDR process unit 123 is transmitted and displayed on the display 41 of the operation device 40 of the video creator, for example.

(Operation of video converter 20)
Next, the operation of the video converter 20 that processes the HDR video with parameter information transmitted from the camera control unit 12 through the main transmission line 30 will be described.

  When the video converter 20 receives the HDR video with parameter information through the main transmission line 30, the CPU 203 extracts the parameter information for HDR adjustment and the parameter information for SDR adjustment from the received HDR video with parameter information. The CPU 203 gives the extracted HDR adjustment parameter information to the inverse HDR process unit 201 and also gives the SDR process unit 202 the SDR adjustment parameter information.

  The inverse HDR processing unit 201 performs inverse conversion on the HDR video using the parameter information for HDR adjustment provided by the CPU 203, and generates a restored pixel signal that restores the original pixel signal. The restored pixel signal is supplied to the SDR process unit 202.

  In the SDR process unit 202, an output video signal corresponding to the SDR video generated in the camera control unit 12 is generated from the restored pixel signal obtained by the inverse HDR process unit 201 using the parameter information for SDR adjustment. To be done. The output video signal corresponding to the generated SDR video is transmitted and displayed on a display different from the display 41 of the operating device 40 to which the SDR video generated by the camera control unit 12 is transmitted, for example.

  As described above, according to the video system 1 of the present embodiment, the camera control unit 12 attaches the parameter information for HDR adjustment and the parameter information for SDR adjustment to the generated HDR video, and then the video converter via the main line transmission line 30. 20. The video converter 20 restores the original pixel signal based on the parameter information for HDR adjustment added to the HDR video, and also includes the parameter information for SDR adjustment added to the HDR video for this restored pixel signal. Then, the output video signal corresponding to the SDR video generated in the camera control unit 12 is reproduced. Accordingly, an output video signal whose expression is as close as possible to the SDR video generated at the same time as the HDR video from the pixel signal in the camera control unit 12 can be obtained by the conversion from the HDR video in the video converter 20.

<Second Embodiment>
Next, a second embodiment according to the present technology will be described.
FIG. 4 is a block diagram showing a configuration of a video system 1A according to the second embodiment of the present technology.
The video system 1A includes an HDR process unit 115 in the image pickup apparatus 11.
The HDR process unit 115 generates an HDR video while performing various adjustments on the pixel signal output from the preprocessor 112 based on the parameter information for HDR adjustment, and supplies the HDR video to the transmission unit 113. The transmitter 113 transmits the HDR video supplied by the HDR process unit 115 to the camera control unit 12 through the camera cable 13.

  The CPU 114 of the image pickup apparatus 11 communicates with the CPU 124 of the camera control unit 12 through the camera cable 13, and provides the parameter information for HDR adjustment used for generating the HDR video in the HDR process unit 115 to the camera control unit. 12 CPUs 124 are notified.

  The camera control unit 12 includes a transmission unit 121, a reverse HDR process unit 125, an SDR process unit 123, and a CPU 124.

  The CPU 124 communicates with the CPU 114 of the image pickup apparatus 11 through the camera cable 13, receives the parameter information for HDR adjustment from the CPU 114 of the image pickup apparatus 11, and gives it to the inverse HDR process unit 125.

  The transmission unit 121 of the camera control unit 12 supplies the HDR video transmitted from the imaging device 11 through the camera cable 13 to the inverse HDR process unit 125 and also sends it to the main line transmission path 30.

  The inverse HDR process unit 125 uses the parameter information for HDR adjustment given by the CPU 124 to generate a restored pixel signal from which the adjustment component has been removed from the HDR video, and supplies the restored pixel signal to the SDR process unit 123.

  The SDR process unit 123 performs a process of generating an SDR video while performing various adjustments on the restored pixel signal based on the SDR adjustment parameter information. The SDR video generated by the SDR process unit 123 is transmitted and displayed on the display 41 of the operation device 40 of the video creator, for example.

  Further, the CPU 124 uses the parameter information for HDR adjustment used for generating the restored pixel signal from the HDR video in the inverse HDR process by the inverse HDR process unit 125 and the SDR process unit 123 to adjust the SDR video. The SDR adjustment parameter information used for the above is added to the HDR video, and the HDR video is controlled to be transmitted to the video converter 20 through the main transmission line 30.

  The HDR process unit 115 of the imaging device 11, the CPU 114, the inverse HDR process unit 125 of the camera control unit 12, the SDR process unit 123, and the CPU 124 correspond to the first processing circuit in the configuration of the present technology.

  The video converter 20 includes a reverse HDR process unit 201, an SDR process unit 202, and a CPU 203. These are the same as the configuration of the video converter 20 of the first embodiment.

[Configurations of Reverse HDR Process Unit 125 and SDR Process Unit 123]
FIG. 5 is a block diagram showing a functional configuration of the inverse HDR process unit 125 and the SDR process unit 123 of the camera control unit 12.

  The inverse HDR process unit 125 includes a deformatter 251, an inverse OETF unit 252, and a black level correction removing unit 253.

  The deformatter 251 releases the HDR video transmission format.

  The inverse OETF unit 252 removes the OETF gamma applied to the HDR video based on the information (the type of OETF) about the HDR transmission gamma, which is a part of the HDR adjustment parameter information.

  The black level correction removing unit 253 cancels the black level correction applied to the HDR video based on the information (HDR-Black) for black level correction which is a part of the parameter information for HDR adjustment. I do.

  The SDR process unit 123 includes a resolution conversion unit 260, an SDR gain adjustment unit 261, a matrix processing unit 263, a black level correction unit 265, a knee detail processing unit 267, a gamma processing unit 268, and a formatter 269. The configuration of the SDR process unit 123 is the same as the configuration of the SDR process unit 202 of the camera control unit 12.

[Operation of this video system 1A]
Next, the operation of the video system 1A will be described.

(Operation of camera system 10)
In the imaging device 11, the pixel signal output from the preprocessor 112 is supplied to the HDR process unit 115, and the HDR process unit 115 adds various adjustments based on the parameter information for HDR adjustment given from the CPU 114. HDR video is generated. The generated HDR video is transmitted to the camera control unit 12 through the camera cable 13 by the transmission unit 113. Further, the CPU 114 of the image pickup apparatus 11 communicates with the CPU 124 of the camera control unit 12 through the camera cable 13, and the parameter information for HDR adjustment used for HDR video adjustment in the HDR process unit 115 is stored in the camera control unit 12. Notify the CPU 124.

The CPU 124 of the camera control unit 12 provides the inverse HDR process unit 125 with the parameter information for HDR adjustment notified from the CPU 114 of the imaging device 11.
Further, the HDR video received by the transmission unit 121 of the camera control unit 12 passes through the inside of the camera control unit 12, is supplied to the main line transmission line 30, and is transmitted to the video converter 20 through the main line transmission line 30. The HDR video received by the transmission unit 121 is also supplied to the inverse HDR process unit 125.

  The inverse HDR processing unit 125 uses the parameter information for HDR adjustment provided by the CPU 124 to generate a restored pixel signal from which the adjustment component has been removed from the HDR video. The generated restored pixel signal is supplied to the SDR process unit 123. Then, in the SDR process unit 123, a process of generating an SDR video is performed on the restored pixel signal while applying various adjustments based on the SDR adjustment parameter information provided from the CPU 124. The generated SDR video is transmitted and displayed on the display 41 of the operation device 40 of the video creator, for example.

  The CPU 124 receives the HDR adjustment parameter information notified from the CPU 114 of the image pickup apparatus 11 and the SDR adjustment parameter information used for adjusting the restored pixel signal in the SDR process unit 123. Control is performed so that the video is added to the HDR video that passes through the inside 12 and is transmitted to the video converter 20 through the main line transmission line 30.

  The operation of the video converter 20 is the same as that of the first embodiment. That is, when the video converter 20 receives the HDR video with parameter information through the main transmission line 30, the CPU 203 extracts the parameter information for HDR adjustment and the parameter information for SDR adjustment from the received HDR video with parameter information. To do. The CPU 203 gives the extracted HDR adjustment parameter information to the inverse HDR process unit 201 and also gives the SDR process unit 202 the SDR adjustment parameter information.

  The inverse HDR processing unit 201 performs inverse conversion on the HDR video using the parameter information for HDR adjustment provided by the CPU 203, and generates a restored pixel signal that restores the original pixel signal. The restored pixel signal is supplied to the SDR process unit 202.

  In the SDR process unit 202, an output video signal corresponding to the SDR video generated in the camera control unit 12 is generated from the restored pixel signal obtained by the inverse HDR process unit 201 using the parameter information for SDR adjustment. To be done. The generated output video signal is transmitted to and displayed on a display different from the display 41 of the operating device 40 to which the SDR video generated by the camera control unit 12 is transmitted, for example.

  As described above, also in the video system 1A of the present embodiment, the output video signal whose expression is as close as possible to the SDR video generated at the same time as the HDR video from the pixel signal in the camera control unit 12 is output from the HDR video in the video converter 20. Can be obtained by converting

<Modification 1>
The camera control unit 12 and the video converter 20 can each be configured using a computer. That is, by installing a program that causes a computer to operate as the camera control unit 12 and the video converter 20 into each computer, a video system having functions equivalent to those of the first and second embodiments described above is realized. be able to.

<Modification 2>
In the above embodiments, the case of processing the HDR video and the SDR video has been described, but the present technology can be generally applied to the case where two video signals are generated from a pixel signal while adjusting differently from each other. However, the present invention is not limited to HDR video and SDR video. In particular, when the different adjustments to the two video signals are color-related adjustments, a video signal that is similar in appearance to the other video signal that is simultaneously generated from the pixel signal can be obtained by conversion from one video signal. ..

<Modification 3>
Further, when the present technology is applied to two video signals having different two dynamic ranges, the video signal to be inverse-converted is determined as in the dynamic range relationship between the HDR video and the SDR video. By setting the wide dynamic range, a video signal generated from the pixel signal in the camera control unit and closer in expression to the narrower dynamic range video signal can be obtained by converting the HDR video in the video converter.

In addition, the present technology may have the following configurations.
(1) The camera system is
A second image different from the first image adjustment parameter is generated based on the first image adjustment parameter from the pixel signal generated by the image pickup unit that picks up an image of a subject and obtains a pixel signal. A second video signal is generated based on the adjustment parameter, and transmission information in which the first adjustment parameter and the second adjustment parameter are added to the second video signal is transmitted via a first transmission path. 1 processing circuit,
The video converter is
Receiving the transmission information via the first transmission path,
Based on the second image adjustment parameter included in the transmission information, the second video signal included in the transmission information is inversely converted to generate a restored pixel signal, and the first pixel included in the transmission information is converted. A second processing circuit that performs an adjustment process corresponding to the first video signal on the restored signal based on one adjustment parameter to generate an output video signal corresponding to the first video signal. Video system.

(2) The video system according to (1) above,
The first image adjustment parameter and the second image adjustment parameter include image adjustment parameters relating to the levels of the first video signal and the second video signal, and the dynamic range of the first video signal is the A video system that is narrower than the dynamic range of the second video signal.

(3) The video system according to (1) or (2) above,
A video system in which the first image adjustment parameter and the second image adjustment parameter include image adjustment parameters relating to colors of the first video signal and the second video signal.

(4) The video system according to any one of (1) to (3) above,
The video system in which the first video signal is SDR (Standard Dynamic Range) video and the second video signal is HDR (High Dynamic Range) video.

(5) The video system according to any one of (1) to (4) above,
From the camera system to the video converter, the first processing circuit and the first processing circuit are arranged so that only the second video signal of the first video signal and the second video signal is transmitted through the second transmission path. The second processing circuit is configured,
The second processing circuit is a video system configured to transmit an output video signal corresponding to the first video signal to a display via a third transmission line different from the second transmission line.

(6) The video system according to any one of (1) to (5) above,
A video system in which the first image adjustment parameter includes a relative range indicating a ratio of a gain for the first video signal and a gain for the second video signal.

(7) The video system according to any one of (1) to (6) above,
A video system in which the first image adjustment parameters include gamut information of the first video signal.

(8) The video system according to any one of (1) to (7) above,
The video system, wherein the first image adjustment parameter includes information for black level correction.

(9) The video system according to any one of (1) to (8) above,
A video system in which the first image adjustment parameters include information about knee correction.

(10) The video system according to any one of (1) to (9) above,
A video system in which the first image adjustment parameter includes information about dynamic range compression.

(11) The video system according to any one of (1) to (10) above,
The video system in which the second image adjustment parameter includes OETF (Optical-Electro Transfer Function) information.

(12) The video system according to any one of (1) to (11) above,
A video system in which the second image adjustment parameter comprises gamut information of the second video signal.

(13) The video system according to any one of (1) to (12) above,
A video system in which the second image adjustment parameter includes information for black level correction.

(14) With the camera system,
A first processing circuit generates a first video signal based on a first image adjustment parameter from the pixel signal generated by an image pickup unit that picks up an image of a subject and obtains a pixel signal. A second video signal based on a second image adjustment parameter different from the above, and the first transmission of transmission information in which the first adjustment parameter and the second adjustment parameter are added to the second video signal. Transmission through the road,
With a video converter,
Receiving the transmission information via the first transmission path,
The second processing circuit inversely transforms the second video signal included in the transmission information to generate a restored pixel signal based on the second image adjustment parameter included in the transmission information, and the transmission is performed. A video for performing an adjustment process corresponding to the first video signal on the restored signal based on the first adjustment parameter included in information to generate an output video signal corresponding to the first video signal. Processing method.

(15) The video processing method according to (14) above,
The first image adjustment parameter and the second image adjustment parameter include image adjustment parameters relating to the levels of the first video signal and the second video signal, and the dynamic range of the first video signal is the A video processing method narrower than the dynamic range of the second video signal.

(16) The video processing method according to (14) or (15) above,
The video processing method, wherein the first image adjustment parameter and the second image adjustment parameter include image adjustment parameters relating to colors of the first video signal and the second video signal.

(17) The video processing method according to any one of (14) to (16) above,
The video processing method, wherein the first video signal is SDR (Standard Dynamic Range) video and the second video signal is HDR (High Dynamic Range) video.

(18) The video processing method according to any one of (14) to (17),
In the first processing circuit and the second processing circuit, only the second video signal of the first video signal and the second video signal from the camera system to the video converter is the second video signal. Transmission through the transmission line,
The video processing method, wherein the second processing circuit transmits an output video signal corresponding to the first video signal to a display via a third transmission line different from the second transmission line.

(19) The video processing method according to any one of (14) to (18) above,
The video processing method, wherein the first image adjustment parameter includes a relative range indicating a ratio of a gain for the first video signal and a gain for the second video signal.

(20) The video processing method according to any one of (14) to (19) above,
The video processing method, wherein the first image adjustment parameter includes color gamut information of the first video signal.

(21) The video processing method according to any one of (14) to (20),
The video processing method, wherein the first image adjustment parameter includes information for black level correction.

(22) The video processing method according to any one of (14) to (21),
The video processing method, wherein the first image adjustment parameter includes information regarding knee correction.

(23) The video processing method according to any one of (14) to (22) above,
The video processing method, wherein the first image adjustment parameter includes information about dynamic range compression.

(24) The video processing method according to any one of (14) to (23),
The video processing method, wherein the second image adjustment parameter includes OETF (Optical-Electro Transfer Function) information.

(25) The video processing method according to any one of (14) to (24),
A video system in which the second image adjustment parameter comprises gamut information of the second video signal.

(26) The video processing method according to any one of (14) to (25),
The video processing method, wherein the second image adjustment parameter includes information for black level correction.

(27) With the camera system,
A second image different from the first image adjustment parameter is generated based on the first image adjustment parameter from the pixel signal generated by the image pickup unit that picks up an image of a subject and obtains a pixel signal. A second video signal is generated based on the adjustment parameter, and transmission information in which the first adjustment parameter and the second adjustment parameter are added to the second video signal is transmitted via a first transmission path. 1 processing circuit,
With a video converter,
Receiving the transmission information via the first transmission path,
Based on the second image adjustment parameter included in the transmission information, the second video signal included in the transmission information is inversely converted to generate a restored pixel signal, and the first pixel included in the transmission information is converted. A computer as a second processing circuit that performs an adjustment process corresponding to the first video signal on the restored signal based on one adjustment parameter, and generates an output video signal corresponding to the first video signal. The program to run.
(28) The program according to (27) above,
The first image adjustment parameter and the second image adjustment parameter include image adjustment parameters relating to the levels of the first video signal and the second video signal, and the dynamic range of the first video signal is the A program that is narrower than the dynamic range of the second video signal.

(29) The program according to (27) or (28) above,
A program in which the first image adjustment parameter and the second image adjustment parameter include image adjustment parameters relating to colors of the first video signal and the second video signal.

(30) The program according to any one of (27) to (29) above,
A program in which the first video signal is SDR (Standard Dynamic Range) video and the second video signal is HDR (High Dynamic Range) video.

(31) The program according to any one of (27) to (30) above,
In the first processing circuit and the second processing circuit, only the second video signal of the first video signal and the second video signal from the camera system to the video converter is the second video signal. Transmission through the transmission line,
A program for causing the second processing circuit to operate the computer to transmit an output video signal corresponding to the first video signal to a display via a third transmission line different from the second transmission line.

(32) The program according to any one of (27) to (31) above,
A program in which the first image adjustment parameter includes a relative range indicating a ratio of a gain for the first video signal and a gain for the second video signal.

(33) The program according to any one of (27) to (32) above,
The program wherein the first image adjustment parameter includes color gamut information of the first video signal.

(34) The program according to any one of (27) to (33) above,
A program in which the first image adjustment parameter includes information for black level correction.

(35) The program according to any one of (27) to (34) above,
A program in which the first image adjustment parameter includes information regarding knee correction.

(36) The program according to any one of (27) to (35) above,
The program wherein the first image adjustment parameter includes information about dynamic range compression.

(37) The program according to any one of (27) to (36) above,
The program in which the second image adjustment parameter includes OETF (Optical-Electro Transfer Function) information.

(38) The program according to any one of (27) to (37) above,
The program wherein the second image adjustment parameter includes color gamut information of the second video signal.

(39) The program according to any one of (27) to (38) above,
A program in which the second image adjustment parameter includes information for black level correction.

(40) A first video signal is generated based on a first image adjustment parameter from the pixel signal generated by an image pickup unit that picks up an image of a subject and obtains a pixel signal, and a first video signal different from the first image adjustment parameter is generated. A second video signal is generated based on the second image adjustment parameter, and transmission information obtained by adding the first adjustment parameter and the second adjustment parameter to the second video signal is transmitted via the first transmission path. A camera system comprising: a first processing circuit for transmitting.

(41) The camera system according to (40) above,
The first image adjustment parameter and the second image adjustment parameter include image adjustment parameters relating to the levels of the first video signal and the second video signal, and the dynamic range of the first video signal is the A camera system that is narrower than the dynamic range of the second video signal.

(42) The camera system according to (40) or (41) above,
The camera system, wherein the first image adjustment parameter and the second image adjustment parameter include image adjustment parameters relating to colors of the first video signal and the second video signal.

(43) The camera system according to any one of (40) to (42) above,
A camera system in which the first video signal is SDR (Standard Dynamic Range) video and the second video signal is HDR (High Dynamic Range) video.

(44) The camera system according to any one of (40) to (43) above,
The camera system in which the first image adjustment parameter includes a relative range indicating a ratio of a gain for the first video signal and a gain for the second video signal.

(45) The camera system according to any one of (40) to (44) above,
A camera system in which the first image adjustment parameter includes color gamut information of the first video signal.

(46) The camera system according to any one of (40) to (45) above,
A camera system in which the first image adjustment parameter includes information for black level correction.

(47) The camera system according to any one of (40) to (46) above,
A camera system in which the first image adjustment parameter includes information about knee correction.

(48) The camera system according to any one of (40) to (47) above,
A camera system in which the first image adjustment parameter includes information about dynamic range compression.

(49) The camera system according to any one of (40) to (48) above,
The camera system in which the second image adjustment parameter includes OETF (Optical-Electro Transfer Function) information.

(50) The camera system according to any one of (40) to (49) above,
A camera system in which the second image adjustment parameter includes color gamut information of the second video signal.

(51) The camera system according to any one of (40) to (50) above,
The camera system in which the second image adjustment parameter includes information for black level correction.

(52) A first video signal is generated based on the first image adjustment parameter from the pixel signal generated by the image pickup unit that picks up an image of a subject to obtain a pixel signal, and a first video signal different from the first image adjustment parameter is generated. A second video signal is generated based on the second image adjustment parameter, and transmission information obtained by adding the first adjustment parameter and the second adjustment parameter to the second video signal is transmitted via the first transmission path. Based on the second image adjustment parameter included in the transmission information transmitted from the transmitting camera system, the second video signal included in the transmission information is inversely converted to generate a restored pixel signal, and An adjustment process corresponding to the first video signal is performed on the restored signal based on the first adjustment parameter included in the transmission information, and the restoration process is performed on the first video signal. Video Converter having a second processing circuit for generating an output video signal to.

(53) The video converter according to (52) above,
The first image adjustment parameter and the second image adjustment parameter include image adjustment parameters relating to the levels of the first video signal and the second video signal, and the dynamic range of the first video signal is the A video converter that is narrower than the dynamic range of the second video signal.

(54) The video converter according to (52) or (53) above,
A video converter, wherein the first image adjustment parameter and the second image adjustment parameter include image adjustment parameters relating to the colors of the first video signal and the second video signal.

(55) The video converter according to any one of (52) to (54) above,
A video converter in which the first video signal is SDR (Standard Dynamic Range) video and the second video signal is HDR (High Dynamic Range) video.

(56) The video converter according to any one of (52) to (55) above,
A video converter in which the first image adjustment parameter includes a relative range indicating a ratio of a gain for the first video signal and a gain for the second video signal.

(57) The video converter according to any one of (52) to (56) above,
A video converter in which the first image adjustment parameter includes color gamut information of the first video signal.

(58) The video converter according to any one of (52) to (57) above,
The video converter, wherein the first image adjustment parameter includes information for black level correction.

(59) The video converter according to any one of (52) to (58) above,
A video converter, wherein the first image adjustment parameters include information about knee correction.

(60) The video converter according to any one of (52) to (59) above,
A video converter, wherein the first image adjustment parameters include information about dynamic range compression.

(61) The camera system according to any one of (52) to (60) above,
The video converter in which the second image adjustment parameter includes OETF (Optical-Electro Transfer Function) information.

(62) The video converter according to any one of (52) to (61) above,
A camera system in which the second image adjustment parameter includes color gamut information of the second video signal.

(63) The video converter according to any one of (52) to (62) above,
The video converter, wherein the second image adjustment parameter includes information for black level correction.

DESCRIPTION OF SYMBOLS 1 ... Video system 10 ... Camera system 11 ... Imaging device 12 ... Camera control unit 13 ... Camera cable 20 ... Video converter 30 ... Main line transmission line 35 ... Output transmission line 114 ... CPU
121 ... Transmission unit 122 ... HDR process unit 123 ... SDR process unit 124 ... CPU
201 ... Inverse HDR process unit 202 ... SDR process unit 203 ... CPU

Claims (18)

A first video signal is generated based on a first image adjustment parameter from the pixel signal generated by an image pickup unit that picks up an image of a subject and obtains a pixel signal, and is wider than the first video signal based on the pixel signal. A camera system having a first processing circuit for generating a second video signal having a dynamic range and transmitting the first image adjustment parameter and the second video signal. The camera system according to claim 1, wherein
A camera system in which the first processing circuit generates a second video signal having a wider dynamic range than the first video signal based on a second image adjustment parameter relating to adjustment of a dynamic range. The camera system according to claim 2, wherein
The first processing circuit converts the first image adjustment parameter, the second image adjustment parameter, and the second video signal into a video converter that generates an output video signal corresponding to the first video signal. Camera system to send. The camera system according to claim 3, wherein
The second video signal has a first resolution,
The camera system wherein the output video signal has a second resolution lower than the first resolution. The camera system according to claim 3 or 4, wherein
A camera system in which the first video signal is SDR (Standard Dynamic Range) video and the second video signal is HDR (High Dynamic Range) video. It is a camera system as described in any one of Claims 1-5, Comprising:
A camera system for outputting the first video signal to a display. It is a camera system as described in any one of Claims 1-6, Comprising:
A camera system in which the first image adjustment parameter includes color gamut information of the first video signal. It is a camera system as described in any one of Claims 1-6, Comprising:
A camera system in which the first image adjustment parameter includes information for black level correction. It is a camera system as described in any one of Claims 1-6, Comprising:
A camera system in which the first image adjustment parameter includes information about knee correction. It is a camera system as described in any one of Claims 1-6, Comprising:
A camera system in which the first image adjustment parameter includes information about dynamic range compression. The camera system according to any one of claims 2 to 10, wherein
A camera system in which the second image adjustment parameter includes a relative range indicating a ratio of a gain for the first video signal and a gain for the second video signal. The camera system according to claim 2, wherein
The camera system in which the second image adjustment parameter includes OETF (Optical-Electro Transfer Function) information. The camera system according to claim 2, wherein
A camera system in which the second image adjustment parameter includes color gamut information of the second video signal. The camera system according to claim 2, wherein
The camera system in which the second image adjustment parameter includes information for black level correction. A first video signal is generated based on a first image adjustment parameter from the pixel signal generated by an image pickup unit that picks up an image of a subject and obtains a pixel signal, and is wider than the first video signal based on the pixel signal. A video processing method for generating a second video signal having a dynamic range and transmitting the first image adjustment parameter and the second video signal. A first video signal is generated based on a first image adjustment parameter from the pixel signal generated by an image pickup unit that picks up an image of a subject and obtains a pixel signal, and is wider than the first video signal based on the pixel signal. A program for operating a computer as a first processing circuit for generating a second video signal having a dynamic range and transmitting the first image adjustment parameter and the second video signal. It has a camera system and a video converter,
The camera system is
A first video signal is generated based on a first image adjustment parameter from the pixel signal generated by an image pickup unit that picks up an image of a subject and obtains a pixel signal, and is wider than the first video signal from the pixel signal. A first processing circuit for generating a second video signal having a dynamic range and transmitting the first image adjustment parameter and the second video signal;
The video converter is
Receiving the first image adjustment parameter and the second video signal received,
A restored pixel signal is generated from the received second video signal, and an output video signal corresponding to the first video signal is generated based on the received first image adjustment parameter and the restored pixel signal. A video system having a second processing circuit. A first video signal is generated based on a first image adjustment parameter from the pixel signal generated by an image pickup unit that picks up an image of a subject and obtains a pixel signal, and is wider than the first video signal based on the pixel signal. A second video signal having a dynamic range is generated, and a restored pixel signal is generated from the second video signal transmitted from a camera system transmitting the first image adjustment parameter and the second video signal, and A second processing circuit for generating an output video signal corresponding to the first video signal based on the first image adjustment parameter and the restored pixel signal.

Images