JP2022007871A5 - Image generation device, camera, control method and program - Google Patents

Description

In order to solve the above problems and achieve the objects, the present invention provides a display device having a display unit capable of displaying an HDR (High Dynamic Range) image or an SDR (Standard Dynamic Range) image. , an image generation device that outputs image data through an external data transmission path, comprising: a light emission characteristic inverse converting means for inversely converting the light emission characteristic of the display section with respect to the image data; and a light emission characteristic of the display section and the HDR. EOTF (Electro-Optical Transfer Function) is smaller than the sum of squares of the difference between the light emission characteristics of the display section and the EOTF of the SDR, and the bit precision of the image data output from the image generation device is is higher than the bit precision of the external data transmission path, and when displaying the HDR image on the display unit, the image data generated by the light emission characteristic inverse conversion means is transmitted through the external data transmission path to the HDR image. and transmitting means for transmitting to the display device .

Further, the present invention outputs image data through an external data transmission path to a display device having a display unit capable of displaying an HDR (High Dynamic Range) image or an SDR (Standard Dynamic Range) image. It is an image generation device that converts image data based on HDR OETF (Optical -Electro TRANSFER FUNCTION) conversion means, and the light emission characteristics of the display and the HDR EotF (EotF (EotF) (EotF). Al TRANSFER FUNCTION) is smaller than the sum of squares of the difference between the light emitting characteristics of the display unit and the EOTF of the SDR, and the bit precision of the image data output from the image generation device is equal to the bit precision of the external data transmission path. The above apparatus further comprises a transmitting means for transmitting image data generated by the HDR OETF converting means to the display device through the external data transmission path when displaying the HDR image on the display section. .

Next, using FIG. 2C, a description will be given of the processing of the emission characteristic inverse conversion unit 208 when the input image data to the emission characteristic inversion unit 208 is YCC (luminance, color difference) data. The YCC RGB conversion unit 208e converts the input YCC data into RGB data. The processing after RGB conversion is the same as that shown in FIG. 2(b). The RGB data subjected to white balance adjustment by the WB section 208d is converted into YCC data by the RGB YCC conversion section 208f and output.

Furthermore, the image data displayed on the display section 246 needs to undergo inverse conversion of the luminescence characteristics before being converted from DA to DA by the DA converter 244 . In this embodiment, when performing HDR display where gradation breakdown is likely to occur, the image data generated by the OETF converter 205, which has a bit precision higher than that of the external data transmission path 220, is emitted by emitting light similar to the HDR OETF. Performs inverse transformation of characteristics. This makes it possible to reduce quantization errors and calculation errors, and minimize gradation breakdown in displayed images.

Claims (20)

An image generation device that outputs image data through an external data transmission path to a display device having a display unit capable of displaying an HDR (High Dynamic Range) image or an SDR (Standard Dynamic Range) image. ,
a light emission characteristic inverse conversion means for inversely converting the light emission characteristic of the display unit with respect to image data;
The sum of squares of the difference between the light emission characteristic of the display section and the EOTF (Electro-Optical Transfer Function) of the HDR is smaller than the sum of squares of the difference between the light emission characteristic of the display section and the EOTF of the SDR, and the image generation device The bit precision of the image data output from the external data transmission path is greater than or equal to the bit precision of the external data transmission path, and when displaying the HDR image on the display section, the image generated by the light emission characteristic inverse conversion means. An image generating device comprising: transmitting means for transmitting data to the display device through the external data transmission path. An image generation device that outputs image data through an external data transmission path to a display device having a display unit capable of displaying an HDR (High Dynamic Range) image or an SDR (Standard Dynamic Range) image. ,
HDR OETF (Optical-Electro Transfer Function) conversion means for converting image data based on HDR OETF;
The sum of squares of the difference between the light emission characteristic of the display section and the EOTF (Electro-Optical Transfer Function) of the HDR is smaller than the sum of squares of the difference between the light emission characteristic of the display section and the EOTF of the SDR, and the image generation device The bit precision of the image data output from the external data transmission path is higher than the bit precision of the external data transmission path, and when displaying the HDR image on the display section, the image data generated by the HDR OETF conversion means. an image generating device, comprising: transmitting means for transmitting the data to the display device through the external data transmission path. HDR OETF conversion means for converting image data based on HDR OETF;
further comprising SDR OETF conversion means for converting the image data based on the SDR OETF,
2. The image generation device according to claim 1, wherein the light emission characteristic inverse conversion means performs inverse conversion of the light emission characteristics of the display section on the image data generated by the HDR OETF conversion means. OETF conversion means for converting image data based on OETF;
further comprising SDR OETF conversion means for converting the image data based on the SDR OETF,
If the image data generated by the OETF conversion means is image data based on the SDR OETF, the HDR OETF conversion means converts it into image data based on the HDR OETF,
2. The SDR OETF converting means, if the image data generated by the OETF converting means is image data based on the HDR OETF, converts the image data into image data based on the SDR OETF. 2. The image generation device according to 2. The display section is an organic EL,
The HDR EOTF is SMPTE STANDARD 2084,
The EOTF of the SDR is RECOMMENDATION ITU-R BT. 709. The image generating device according to claim 1 or 2, wherein the image generating device is 709. The external data transmission path has a bit precision of 10 bits or less,
MIPI (Mobile Industry Processor Interface) (registered trademark), LVDS (Low Voltage Differential Signaling), subLVDS, HDMI (High-Definition Multimedia Interface) (registered trademark), Display Port (registered trademark), or SDI (Serial Digital Interface) The image generation device according to any one of claims 1 to 5 . further comprising a color gamut conversion means for converting the image data generated by the emission characteristic inverse conversion means into a color gamut that matches the display performance of the display unit,
The color gamut conversion means includes:
inverse gamma conversion means for converting the image data generated by the emission characteristic inverse conversion means into linear gamma;
color gamut calculation means for converting the image data generated by the inverse gamma conversion means into the color gamut of the display unit;
The image according to claim 1, further comprising gamma conversion means for converting the image data obtained by the color gamut calculation means into a gamma similar to that of the image data generated by the emission characteristic inverse conversion means. generator. further comprising color gamut conversion means for converting the image data generated by the HDR OETF conversion means into a color gamut that matches the display performance of the display unit,
The color gamut conversion means includes:
inverse gamma conversion means for converting the image data generated by the HDR OETF conversion means into linear gamma;
color gamut calculation means for converting the image data generated by the inverse gamma conversion means into the color gamut of the display unit;
5. A gamma conversion means for converting the image data obtained by the color gamut calculation means into a gamma similar to that of the image data generated by the HDR OETF conversion means. Image generation device. further comprising a color gamut conversion means for converting the image data generated by the emission characteristic inverse conversion means into a color gamut that matches the display performance of the display unit,
The color gamut conversion means includes:
inverse gamma conversion means for converting the image data generated by the emission characteristic inverse conversion means into linear gamma;
gain calculation means for adding gain to the image data generated by the inverse gamma conversion means;
Image generation according to claim 1, further comprising gamma conversion means for converting the image data obtained by the gain calculation means into a gamma similar to that of the image data generated by the emission characteristic inverse conversion means. Device. further comprising color gamut conversion means for converting the image data generated by the HDR OETF conversion means into a color gamut that matches the display performance of the display unit,
The color gamut conversion means includes:
inverse gamma conversion means for converting the image data generated by the HDR OETF conversion means into linear gamma;
gain calculation means for adding gain to the image data generated by the inverse gamma conversion means;
The image according to claim 2 or 4 , further comprising gamma conversion means for converting the image data obtained by the gain calculation means into a gamma similar to that of the image data generated by the HDR OETF conversion means. generator. 11. The image generation device according to claim 9 , wherein the gain calculation means has a matrix calculation function and also functions as a color gamut calculation. 12. The image generation device according to claim 7 , wherein the color gamut of the image data generated by the inverse gamma conversion means corresponds to the HDR color gamut. The image generation device according to claim 7 , wherein the color gamut of the display unit corresponds to the color gamut of SDR. further comprising a first image selection means for selecting either the image data generated by the emission characteristic inverse conversion means or the image data generated by the SDR OETF conversion means,
4. The image generation device according to claim 3 , wherein the image data selected by the first image selection means is output to the display device through the external data transmission path. further comprising a first image selection means for selecting either the image data generated by the HDR OETF conversion means or the image data generated by the SDR OETF conversion means,
5. The image generation device according to claim 4, wherein the image data selected by the first image selection means is output to the display device through the external data transmission path. The first image selection means is configured such that the sum of squares of the difference between the light emission characteristic of the display section and the EOTF (Electro-Optical Transfer Function) of the HDR is equal to the sum of squares of the difference between the light emission characteristic of the display section and the EOTF of the SDR. If it is determined that the image data is not smaller than the sum of squares , the image data generated by the SDR OETF conversion means is selected, and the sum of squares of the difference between the light emission characteristics of the display section and the HDR EOTF (Electro-Optical Transfer Function) is determined. is smaller than the sum of squares of the difference between the light emitting characteristics of the display section and the EOTF of the SDR , the bit precision of the image data generated by the OETF conversion means and the bit precision of the external data transmission path Compare the
If the first image selection means determines that the bit precision of the image data generated by the OETF conversion means is smaller than the bit precision of the external data transmission path, the first image selection means selects the image data generated by the SDR OETF conversion means. is selected, and if it is determined that the bit precision of the image data generated by the OETF conversion means is greater than or equal to the bit precision of the external data transmission path, determining whether the image to be displayed is HDR;
When the first image selection means determines that the image to be displayed is not HDR, the first image selection means selects the image data generated by the SDR OETF conversion means, and when the first image selection means determines that the image to be displayed is HDR, 15. The image generation device according to claim 14 , wherein image data generated by the light emission characteristic inverse conversion means is selected. The first image selection means is configured such that the sum of squares of the difference between the light emission characteristic of the display section and the EOTF (Electro-Optical Transfer Function) of the HDR is equal to the sum of squares of the difference between the light emission characteristic of the display section and the EOTF of the SDR. If it is determined that the image data is not smaller than the sum of squares , the image data generated by the SDR OETF conversion means is selected, and the sum of squares of the difference between the light emission characteristics of the display section and the HDR EOTF (Electro-Optical Transfer Function) is determined. is smaller than the sum of squares of the difference between the light emitting characteristics of the display section and the EOTF of the SDR , the bit precision of the image data generated by the OETF conversion means and the bit precision of the external data transmission path Compare the
If the first image selection means determines that the bit precision of the image data generated by the OETF conversion means is smaller than the bit precision of the external data transmission path, the first image selection means selects the image data generated by the SDR OETF conversion means. is selected, and if it is determined that the bit precision of the image data generated by the OETF conversion means is greater than or equal to the bit precision of the external data transmission path, determining whether the image to be displayed is HDR;
When the first image selection means determines that the image to be displayed is not HDR, the first image selection means selects the image data generated by the SDR OETF conversion means, and when the first image selection means determines that the image to be displayed is HDR, The image generation device according to claim 15 , wherein image data generated by the HDR OETF conversion means is selected. A camera comprising: the image generation device according to claim 1; the display device; and the external data transmission path. A method for controlling an image generation device that outputs image data through an external data transmission path to a display device having a display unit capable of displaying an HDR (High Dynamic Range) image or an SDR (Standard Dynamic Range) image. And,
performing inverse conversion of the light emitting characteristics of the display unit on the image data;
The sum of squares of the difference between the light emission characteristic of the display section and the EOTF (Electro-Optical Transfer Function) of the HDR is smaller than the sum of squares of the difference between the light emission characteristic of the display section and the EOTF of the SDR, and the image generation device The bit precision of the image data output from the external data transmission path is higher than the bit precision of the external data transmission path, and when displaying the HDR image on the display section, the inversely converted image data is transferred to the external data. A control method comprising the step of transmitting data to the display device through a transmission path. A program for causing a computer to execute the control method according to claim 19 .