JP6581862B2 - Video camera for HDR-SDR integrated production - Google Patents

Description

  For HDR-SDR integrated production video camera, HDR (High Dynamic Range) video signal and SDR (Standard Dynamic Range) video signal are produced at the same time by using optical aperture and electronic aperture. Related to video cameras. The present invention also relates to an aperture operating device for a video camera. Here, the video camera is not limited to a video camera that produces a broadcast video signal, but means any device that produces HDR and SDR video signals from video.

  In recent years, with the practical application of high-resolution images such as Super Hi-Vision, there has been a demand for realistic images such as wide-gamut display-type images and high-luminance images. Recommendations from the International Telecommunication Union Radiocommunications Sector (ITU-R) BT. The introduction of an HDR (High Dynamic Range) video system capable of highlight expression, which is impossible with SDR (Standard Dynamic Range), which is a conventional dynamic range defined in 709 (Non-Patent Document 1), is being studied. Here, the “dynamic range” is a range (video signal range) from the black level to the peak level that expresses an image, and the higher this is, the more the range from white to highlight can be shown without compression. .

  The SDR video is ITU-R recommendation BT. As defined in 709, the video signal is produced in a video signal range from 0% to about 109% with the video signal 100% as a reference white level. That is, the reference white level is set to 235 out of the 8-bit (0 to 255) video signal level. Therefore, since the video signal level that can be used to express highlights higher than the reference white level is limited, the brightness of high-brightness subjects such as specular reflection and backlighting is greatly compressed and expressed as a result. Changes in hue will occur. On the other hand, in HDR, by setting the reference white level around the middle of the video signal range, it becomes possible to assign a video signal to a highlight portion (over-white portion) that could not be expressed in SDR. Video expression including

  On the imaging side of the HDR video system, a camera with a wide dynamic range is used to acquire a video with a wide luminance range from the dark part to the bright part, and a signal based on predetermined opto-electric conversion characteristics (OETF) By processing, the black level, the reference white level, and the highlight portion exceeding the reference white level are converted into a video signal of a predetermined range. On the display side, an image including a highlight portion is reproduced by using a display having a higher peak luminance than the conventional display.

  There is a significant difference between HDR and SDR during imaging. In the case of SDR video production, since the dynamic range that can be expressed simultaneously is narrow, depending on the brightness of the scene, the camera iris (aperture, optical aperture) and video so that the subject of interest falls within the predetermined video signal range. The signal gain needs to be adjusted greatly. Therefore, for example, when focusing on a sunny subject, the shade portion cannot be expressed because the iris is narrowed down, and when focusing on a shaded subject, the iris portion cannot be expressed because the iris is opened. On the other hand, in the case of HDR video production, the high dynamic range can be utilized to express the sun from the shade while adjusting the iris and gain of the camera as much as possible.

Recommendation ITU-R BT.709 "Parameter values for the HDTV standards for production and international program exchange"

  Since current broadcasting is SDR, when HDR is introduced, it is required to simultaneously produce an HDR video program and an SDR video program. One method is to acquire video in HDR and automatically convert the HDR video to SDR video, but as described above, processing such as iris adjustment according to the brightness of the subject of interest in the scene Therefore, it is extremely difficult to perform automatically in accordance with the scene, and conversion from HDR to SDR must be performed manually by a colorist or a video engineer, and cannot be used in live broadcasting. There is also a proposal to incorporate SDR and HDR imaging systems using two imaging elements inside one video camera, but such a video camera is expensive and passes through a lens. Since the sensitivity deteriorates, it is not possible to obtain a high-quality video.

  There is no video camera that can perform HDR and SDR video adjustments (iris adjustment, etc.) at the same time in live broadcasting or integrated production of HDR video and SDR video assuming shooting by a cameraman alone. It was difficult to shoot with both broadcast quality.

  Therefore, an object of the present invention made in view of the above problems is to produce an SDR video signal and an HDR video signal by one shooting without requiring complicated conversion from HDR video to SDR video. An object is to provide a video camera for HDR-SDR integrated production.

  In order to solve the above problems, an HDR-SDR integrated production video camera according to the present invention includes an optical aperture that controls incident light to the video camera, and an electronic aperture that controls the gain of a video signal. An HDR video signal controlled only by an aperture and an SDR video signal controlled by both the optical aperture and the electronic aperture are output.

  The HDR-SDR integrated production video camera includes an optical aperture that controls incident light to the video camera, an image sensor that receives the incident light and outputs a video signal, and a predetermined video in the video signal. A video adjustment unit that performs adjustment processing; an HDR signal correction unit that performs HDR knee / gamma processing on the output of the video adjustment unit; and an electronic aperture that performs gain adjustment on the output of the video adjustment unit; It is desirable to provide an SDR signal correction unit that performs SDR knee / gamma correction on the output of the electronic aperture.

  The HDR-SDR integrated production video camera includes an optical aperture that controls incident light to the video camera, an image sensor that receives the incident light and outputs a video signal, and a predetermined video in the video signal. An image adjustment unit that performs adjustment processing, an HDR signal correction unit that performs HDR knee / gamma processing on the output of the image adjustment unit, and an electronic device that performs gain adjustment on the output of the HDR signal correction unit It is desirable to include an aperture and a signal correction unit for SDR that performs SDR knee / gamma correction on the output of the electronic aperture.

  According to the HDR-SDR integrated production video camera of the present invention, it is possible to produce an SDR video signal and an HDR video signal by one shooting, and it is not necessary to convert from HDR video to SDR video. High-efficiency SDR / HDR video integrated live production becomes possible.

It is a block diagram of the video camera for HDR-SDR integrated production of a 1st Example. It is an example of the knee gamma processing function used by this invention. It is a block diagram of the video camera for HDR-SDR integrated production of a 2nd Example. It is an example of the aperture operation apparatus of the video camera of this invention.

  Embodiments of the present invention will be described below.

(Embodiment 1)
As Embodiment 1, an HDR-SDR integrated production video camera will be described. FIG. 1 is an example of a signal processing block of a video camera for HDR-SDR integrated production as a first embodiment.

  The HDR-SDR integrated production video camera 100 includes an optical aperture 10, an image sensor 20, an analog / digital conversion (ADC) unit 30, a video adjustment unit 40, an HDR knee / gamma unit 50, and an electronic aperture. (Gain controller) 60, SDR knee / gamma unit 70, and two SDI (Serial Digital Interface) processing units 80.

  The video adjustment unit 40 includes therein a black level adjustment unit 41, a white level adjustment unit 42, a flare correction / shading adjustment unit 43, a gain adjustment unit 44, and a detail adjustment unit 45. The SDI processing unit 80 includes an SDI encoder unit 81 and an SDI driver unit 82.

  The outline of the production process of the video signal (video signal) will be described together with the function of each block.

  The amount of light of the image (incident light) is controlled by the iris of the camera, that is, the optical aperture 10. The optical aperture 10 can be manually adjusted by a cameraman according to the overall brightness of the image. An operation device for adjusting the optical aperture 10 will be described later. The image (incident light) with the light amount controlled is input to the image sensor 20.

  The image sensor 20 is configured by a CCD (Charge-Coupled Device), for example, and receives an image that has passed through the optical aperture 10. The image sensor (CCD) 20 performs photoelectric conversion of an image using a photodiode or the like, and outputs an electrical signal corresponding to the luminance of each pixel as an image signal. Note that the image sensor 20 has a sufficient dynamic range corresponding to the HDR dynamic range. The image pickup device is not limited to a CCD, and an arbitrary structure such as a MOS type image pickup device can be used.

  An analog / digital conversion (ADC) unit 30 converts an analog video signal output from the image sensor 20 into a digital video signal. In analog / digital conversion processing, necessary analog signal processing for a video signal and signal processing such as pre-knee (KNEE) processing may be performed in the preceding stage. The converted digital video signal is output to the video adjustment unit 40.

  The signal processing performed in the video adjustment unit 40 is signal adjustment processing performed in a normal photographing system.

  The black level adjustment unit 41 adjusts the black level of the digital video signal to be the black reference level of the video signal. Further, the white level adjustment unit 42 adjusts the white level of the digital video signal so as to become the white reference level of the video signal.

  The flare correction / shading adjustment unit 43 corrects that the peripheral video is darker than the central part of the input video signal, and adjusts the shadow of the video to obtain the contrast of the original video. Make adjustments to get closer.

  The gain adjusting unit 44 adjusts the gain of the video signal according to the brightness of the video. Further, the gain adjustment of each of the RGB signals is performed, and the white balance is adjusted.

  The detail adjustment unit 45 performs processing such as enhancement processing of density change at the edge portion of the image and making the edge stand out.

  The signal processing of the video adjustment unit 40 is not limited to these adjustment units 41 to 45, and any adjustment unit can be added or omitted according to the required video adjustment. Further, the processing order of each adjustment unit is not limited to the order shown in the figure, and can be performed in an arbitrary order by giving priority to necessary processing. The output of the video adjustment unit 40 that has performed each of these adjustment processes is branched into two to create an HDR video signal and an SDR video signal, one of which is input to the HDR knee / gamma unit 50 and the other. Is input to an electronic aperture (gain control unit) 60.

  The HDR knee / gamma unit (HDR signal correction unit) 50 performs HDR knee / gamma processing on the output signal from the video adjustment unit 40. Here, knee (KNEE) is a process that compresses the signal of the high-brightness part of the video so that it falls within the dynamic range of the video signal, and gamma correction is a nonlinear output of video with respect to the input signal of the display. This is a process of correcting the video signal so as to compensate the relationship (so that the video intensity is linear with respect to the video signal). In the case of HDR, since the dynamic range is wide, KNEE is not applied, but compression is performed on a very high brightness image such as a strong backlight image depending on the production intention and camera performance. The signal processed by the HDR knee / gamma unit 50 is input to the SDI processing unit 80.

  The SDI processing unit 80 converts an uncompressed digital video signal and a digital audio signal into high-speed serial interface standard data so that the digital video signal and the digital audio signal can be sent with one coaxial cable, and an HDR video signal (HDR video signal). Is output. First, the SDI encoder 81 converts the video signal from the HDR knee / gamma unit 50 into predetermined SDI signal data, and the SDI driver 82 converts the SDI signal into a predetermined format that can be transmitted by a cable. Adjust the output. The SDI processing unit 80 is an example of an output processing unit, and other output processing units can be used according to the output data format.

  In this way, the HDR video signal (HDR video signal) is output from the output processing unit in the HDR signal processing line.

  On the other hand, the electronic aperture (gain adjustment unit) 60 is used to produce an SDR video signal. The gain control of the video signal is performed on the output signal from the video adjustment unit 40 so that the subject of interest is appropriately expressed in the SDR video signal range. The electronic aperture 60 does not optically adjust the image (light quantity) but adjusts the positive or negative gain with respect to the video signal. As a result, the exposure is adjusted by the optical aperture (iris). Since the same operation as described above is given to the video signal for SDR, it is called an electronic aperture. The gain control by the electronic aperture 60 can be manually adjusted by a cameraman in accordance with the overall brightness of the image, similarly to the optical aperture. An operation device for adjusting the electronic aperture 60 will be described later.

  The SDR knee / gamma unit (SDR signal correction unit) 70 performs SDR knee / gamma processing on the signal after the electronic aperture / gain adjustment. Note that the knee / gamma processing for SDR may be performed by the knee / gamma processing established in the conventional SDR video. The image for SDR has been adjusted to the optimum brightness (signal level) for the subject of interest by the cameraman using the optical aperture 10 and the electronic aperture 60. Properly converted to video signal. The signal processed by the SDR knee / gamma unit 70 is input to the SDI processing unit 80.

  The subsequent processing in the SDI processing unit 80 is the same as the HDR signal processing, and the SDI encoder 81 and the SDI driver 82 convert the uncompressed digital video signal and digital audio signal into high-speed serial interface standard data. And output. Instead of the SDI processing unit 80, another output processing unit can be used according to the output data format.

  In this way, the SDR video signal (SDR video signal) is output from the output processing unit in the SDR signal processing line.

  As described above, according to the HDR-SDR integrated production video camera of the present invention, it is possible to simultaneously produce an HDR video signal (HDR video signal) and an SDR video signal (SDR video signal) by one shooting.

  FIG. 2 shows an example of a processing function 51 for performing HDR knee / gamma processing and a processing function 71 for performing SDR knee / gamma processing. In the figure, “Y” on the horizontal axis means normalized luminance, and “V” on the vertical axis means normalized video signal level. As the SDR knee / gamma processing function 71, a conventionally established SDR function can be used. As the HDR knee / gamma processing function 51, for example, a nonlinear conversion characteristic function (OETF) represented by the following equation (1) can be used.

・Eはリファレンスホワイトで正規化され、光強度に対してリニア
・r = 0.5, a= 0.17883277, b= 0.28466892, c= 0.55991073

E is normalized with reference white and is linear with respect to light intensity.r = 0.5, a = 0.17883277, b = 0.28466892, c = 0.55991073

  As shown in FIG. 2, in the HDR knee / gamma processing function 51, the reference white level (sqrt (Y) = 1) is 50% of the video signal range, but in the SDR knee / gamma processing function 71, The reference white level (sqrt (Y) = 1) is close to 100% of the video signal range, and the high luminance area is compressed.

  FIG. 3 shows an example of the signal processing block of the HDR-SDR integrated production video camera according to the second embodiment of the present invention. The processing after the video adjustment unit 40 is different from the signal processing block of the first embodiment.

  The HDR-SDR integrated production video camera 110 according to the second embodiment includes an optical aperture 10, an image sensor 20, an analog / digital conversion (ADC) unit 30, a video adjustment unit 40, an HDR knee gamma. Unit 50, electronic aperture (gain control unit) 60, SDR knee / gamma unit 70, and two SDI processing units 80. Each component block is the same as that of the first embodiment (FIG. 1), and the description of the same contents as those of the first embodiment is omitted or simplified.

  The outline of the production process of the video signal (video signal) will be described together with the function of each block.

  The amount of light of the image (incident light) is adjusted by the optical aperture 10 and input to the image sensor 20. The optical aperture 10 can be manually adjusted by a cameraman according to the overall brightness of the image.

  The image sensor 20 performs photoelectric conversion of the image whose light amount has been adjusted and outputs an analog video signal, and an analog / digital conversion (ADC) unit 30 is output from the image sensor 20. The analog video signal is converted into a digital video signal and output to the video adjustment unit 40.

  The video adjustment unit 40 performs predetermined signal adjustment processing by the black level adjustment unit 41, the white level adjustment unit 42, the flare correction / shading adjustment unit 43, the gain adjustment unit 44, the detail adjustment unit 45, and the like. The digital video signal is input to the HDR knee / gamma unit 50.

  In the HDR knee / gamma unit (HDR signal correction unit) 50, for example, processing based on the HDR knee / gamma processing function 51 shown in FIG. 2 is performed, so that the video signal falls within the HDR dynamic range. Signal level conversion processing is performed. The signal processed by the HDR knee / gamma unit 50 is branched into two to create an HDR video signal and an SDR video signal, one of which is input to the HDR SDI processing unit 80, and the other is Input to an electronic aperture (gain control unit) 60.

  The HDR SDI processing unit 80 converts the input video signal into high-speed serial interface standard data and outputs it. As a result, the HDR video signal is output from the output processing unit in the HDR signal processing line.

  On the other hand, the electronic aperture (gain adjustment unit) 60 is used to produce an SDR video signal. The gain control of the video signal is performed on the output signal from the HDR knee / gamma unit 50 so that the subject of interest is properly expressed in the SDR video signal range. The gain control by the electronic aperture 60 can be manually adjusted by a cameraman in accordance with the overall brightness of the image, similarly to the optical aperture.

  The SDR knee / gamma unit (SDR signal correction unit) 70 performs SDR knee / gamma processing on the signal after the electronic aperture / gain adjustment. For example, processing based on the SDR knee / gamma processing function 71 shown in FIG. 2 is performed, and signal level conversion processing is performed so that the video signal falls within the SDR dynamic range. The processing performed by the HDR knee / gamma unit 50 functions as pre-knee processing (knee processing performed at an early stage prior to the original knee / gamma processing) on the SDR video signal.

  The signal processed by the SDR knee / gamma unit 70 is input to the SDI processing unit 80 and converted into high-speed serial interface standard data. Then, the SDR video signal is output from the output processing unit in the SDR signal processing line.

  According to the HDR-SDR integrated production video camera of the second embodiment, an SDR video signal (video signal) and an HDR video signal (video signal) can be produced simultaneously by one shooting, and the SDR video signal On the other hand, pre-knee processing in the HDR knee / gamma unit 50 and signal processing in the SDR knee / gamma unit 70 can be performed in an overlapping manner, and more appropriate video adjustment processing can be performed.

(Embodiment 2)
The following describes the aperture operation device of the HDR-SDR integrated production video camera described in the first embodiment as the second embodiment of the present invention.

  FIG. 4 is a diagram illustrating an example of the aperture operating device 200, and for the sake of explanation, the aperture adjustment unit is emphasized.

  The aperture operating device 200 has a cylindrical main body (cylindrical portion) 11 and has an attachment portion 12 connected to the video camera body at one end thereof. The cylindrical main body 11 can be provided with an optical aperture inside as in the case of an ordinary camera diaphragm mechanism.

  The aperture operating device 200 is provided with a ring-shaped optical aperture adjustment unit 13 that can rotate, and a ring-shaped electronic aperture adjustment unit 14 that can also perform a rotation operation. A fixed index 15 is provided for grasping the rotation angle of each aperture. Note that the optical aperture adjustment unit 13 and the electronic aperture adjustment unit 14 are not limited to a ring shape, but may have any structure that can be manually operated (for example, a slide switch or an electronic switch). If the optical aperture and the electronic aperture are used, the same operability as that of the conventional aperture can be maintained. Both adjustment units 13 and 14 can be adjusted manually during shooting.

  In addition, the aperture operation device 200 may be provided with various control units (not shown) for adjusting the lens position of the camera, such as a focus ring and a zoom ring.

  The optical aperture adjustment unit 13 has the same structure as the adjustment unit of an optical aperture (iris) of a general camera. For example, an F value (2.8, 4, 5.6, 8, 11, 16, etc.) is described in the ring-shaped adjustment unit 13, and the opening of the optical aperture 10 is adjusted by matching the desired F value with the index 15. To do. The optical aperture is adjusted by controlling the rotation angle of the optical aperture ring 13.

  The electronic aperture adjustment unit 14 is a mechanism for adjusting the electronic aperture (gain control unit) 60 shown in FIGS. 1 and 3 and has a characteristic structure of the present invention. Manual operation is possible in the same manner as the unit 13. For example, the ring-shaped adjustment unit 14 describes an exposure value (Exposure Value) control range (for example, -1EV to + 2EV), and adjusts the electronic aperture by matching the desired exposure value with the index 15. . The parameter value (exposure value) selected by the control unit 14 is transmitted to, for example, the video camera body via the attachment unit 12 and is used as a gain adjustment value by the digital signal processing unit (electronic aperture / gain control unit 60) inside the camera. Is set. Here, the exposure value is generally determined by the exposure time (shutter speed) and the aperture (F) value. When the exposure time is constant, 1EV of the electronic aperture corresponds to one stage (1 stop) of the optical aperture.

  In addition, when adjusting a video signal by electronic amplification (gain), noise may be generated. Therefore, the control range of the electronic aperture, that is, the adjustment range of the electronic aperture adjustment unit 14 is limited to a predetermined range. Is desirable. When the adjustment amount by the electronic aperture adjustment unit 14 exceeds this predetermined range, the optical aperture adjustment unit 13 may perform the adjustment.

  As described above, the aperture operating device for a video camera according to the present invention includes a ring for adjusting the electronic aperture in addition to the conventional optical aperture. The electronic aperture is provided adjacent to the optical aperture, and both operations can be performed in the same manner as conventional aperture adjustment.

  As is apparent from the configuration of the signal processing block in FIGS. 1 and 3, the size of the video signal of the SDR video can be adjusted using either the optical aperture adjustment unit 13 or the electronic aperture adjustment unit 14. The magnitude of the video signal of the HDR video can be adjusted only by the optical aperture adjustment unit 13. Since the HDR video has a wide dynamic range, it is not necessary to adjust the aperture for each scene or subject after adjusting the amount of incident light by the optical aperture adjustment unit 13. Therefore, for example, after adjusting the optical aperture so that the HDR image is appropriately within the range of the HDR video signal level by adjusting the optical aperture adjusting unit 13 first, the adjustment of the SDR image is mainly performed by the electronic aperture adjustment. This can be done using the unit 14. As a result, both HDR video and SDR video can be produced by one person with almost the same operation feeling as before.

  Furthermore, the following interlocking mechanism can be incorporated in the aperture operation device 200 so that the optical aperture and the electronic aperture can be operated in association with each other.

(Interlocking mechanism 1)
The electronic aperture adjustment unit (electronic aperture ring) 14 has a predetermined exposure value variable range (for example, -1 EV to +2 EV). When the electronic aperture ring 14 tries to rotate beyond this range, the optical aperture ring 13 is locked to the electronic aperture ring 14 so that both rings move simultaneously, and the movement of the electronic aperture ring 14 is the movement of the optical aperture ring 13. I was transferred to. That is, even if the electronic aperture ring 14 is rotated beyond the predetermined variable range, the electronic aperture remains set at the upper limit value (for example, + 2EV), and the subsequent rotational movement is for controlling the optical aperture. The rotation angle.

  Thereby, it is possible to perform control with the electronic aperture in the predetermined exposure range, and to adjust the exposure with the optical aperture in the range exceeding the predetermined range. Note that when adjusting the optical aperture, the lock is released so that only the optical aperture ring 13 can be adjusted.

(Interlocking mechanism 2)
When the electronic aperture adjustment unit (electronic aperture ring) 14 is rotated, the optical aperture ring 13 is rotated at a preset rotation angle ratio (for example, 0.2) with respect to the rotation angle of the electronic aperture ring 14. .

  Thereby, the optical aperture can be finely adjusted in conjunction with the adjustment amount of the electronic aperture. It should be noted that it is desirable that this rotation angle ratio can be selected from several types such as 0.1 and 0.3.

(Interlocking mechanism 3)
This is a combination of the interlocking mechanism 1 and the interlocking mechanism 2, and when the electronic aperture ring 14 is rotated, the optical aperture ring 13 is set at a preset rotation angle ratio (for example, 0.2) with respect to the rotation angle of the electronic aperture ring 14. In addition, when the control amount of the electronic aperture ring 14 exceeds the variable range of the exposure value, the optical aperture ring 13 is locked to the electronic aperture ring 14 so that both rings move at the same time. The movement of 14 is transferred to the movement of the optical aperture ring 13.

  As a result, the optical aperture can be finely adjusted within the predetermined range in conjunction with the adjustment amount of the electronic aperture. When the predetermined range is exceeded, the electronic aperture is fixed to the maximum (or minimum) value. Thereafter, it can be controlled by an optical aperture.

  With such an interlocking mechanism, for example, when the gain is increased by the electronic aperture, the S / N ratio of the video signal is deteriorated. However, the S / N ratio is also deteriorated by opening the optical aperture and increasing the video signal level. Can be suppressed. In addition, when the gain is reduced with an electronic aperture for an extremely high-brightness image, there is a possibility that the signal range may be exceeded even in HDR, so that the optical aperture can be reduced to some extent.

  As described above, according to the aperture operating device according to the second embodiment, the cameraman can easily adjust the electronic aperture and the optical aperture, and not only the SDR but also the HDR can be produced in an appropriate range. .

  Although the above embodiment has been described as a representative example, it will be apparent to those skilled in the art that many changes and substitutions can be made within the spirit and scope of the invention. Therefore, the present invention should not be construed as being limited by the above-described embodiments, and various modifications and changes can be made without departing from the scope of the claims. For example, a plurality of constituent blocks described in the embodiments can be combined into one, or one constituent block can be divided.

DESCRIPTION OF SYMBOLS 10 Optical aperture 11 Cylindrical part 12 Attachment part 13 Optical aperture adjustment part 14 Electronic aperture adjustment part 20 Image sensor 30 Analog / digital conversion (ADC) part 40 Image | video adjustment part 41 Black level adjustment part 42 White level adjustment part 43 Flare correction | amendment / Shading adjustment unit 44 Gain adjustment unit 45 Detail adjustment unit 50 HDR knee / gamma unit 60 Electronic aperture (gain control unit)
70 SDR knee / gamma unit 80 SDI processing unit 81 SDI encoder unit 82 SDI driver unit 100, 110 HDR-SDR integrated production video camera 200 Aperture operation device

Claims (3)

  An HDR (High Dynamic Range) video signal controlled only by the optical aperture, an optical aperture for controlling incident light to the video camera, and an electronic aperture for controlling the gain of the video signal, the optical aperture, and the optical aperture A HDR-SDR integrated production video camera that outputs SDR (Standard Dynamic Range) video signals controlled by both electronic apertures. The HDR-SDR integrated production video camera according to claim 1,
An optical aperture that controls the incident light on the video camera;
An image sensor that receives the incident light and outputs a video signal;
A video adjustment unit that performs a predetermined video adjustment process on the video signal;
An HDR signal correction unit that performs HDR knee / gamma processing on the output of the video adjustment unit;
An electronic aperture that performs gain adjustment on the output of the video adjustment unit;
An HDR-SDR integrated production video camera comprising an SDR signal correction unit that performs SDR knee / gamma correction on the output of the electronic aperture. The HDR-SDR integrated production video camera according to claim 1,
An optical aperture that controls the incident light on the video camera;
An image sensor that receives the incident light and outputs a video signal;
A video adjustment unit that performs a predetermined video adjustment process on the video signal;
An HDR signal correction unit that performs HDR knee / gamma processing on the output of the video adjustment unit;
An electronic aperture that performs gain adjustment on the output of the HDR signal correction unit;
An HDR-SDR integrated production video camera comprising an SDR signal correction unit that performs SDR knee / gamma correction on the output of the electronic aperture.

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