HSI to xvYCC Converter - Color Space Converter
HSI color space introduction
Also known as the HSI color space.There are 3 channels in total, hue,range from 0 to 360.saturation,range from 0 to 100.intensity,range from 0 to 255.
Origin: The HSI color space was designed to better match the color perception characteristics of the human eye, suitable for processing color-related information.
Primary Names: HSI, which includes H (Hue), S (Saturation), and I (Intensity) as the three color channels.
Typically expressed as a triplet, for example: hsi(120°, 0.5, 0.75) represents a green hue with medium saturation and high brightness.
Usage Scope: Extensively used in image processing and analysis, such as color segmentation, edge detection, target tracking, etc.
Additionally, HSI can be converted to and from RGB, and while similar to HSV and HSL, in HSI, I (Intensity) represents the overall brightness of the color.
xvYCC color space introduction
Also known as the xvYCC color space.There are 3 channels in total,Y,range from 0 to 255.Cb,range from 0 to 255.Cr,range from 0 to 255.
xvYCC was developed by Sony and standardized by the International Electrotechnical Commission (IEC) in 2005. It is an expansion over the standard YCbCr color space, designed to support a wider range of colors for high-definition video.
The main name is xvYCC, also known as IEC 61966-2-4 or extended-gamut YCC.
Similar to YCbCr, xvYCC is typically expressed as three component values (Y, Cb, Cr). However, xvYCC uses a signaling method that enables it to represent a broader range of colors. This includes values for Cb and Cr that, unlike YCbCr, can exceed the nominal range of video levels, going below 16 or above 235 in 8-bit terms.
xvYCC is used primarily in high-definition video formats and devices such as Blu-ray players, digital cameras, and HDTVs that support HDMI 1.3 or higher. It allows for more vivid and accurate color representation on capable devices.
xvYCC can display a wider range of color values than sRGB by allowing values that fall outside the typical RGB gamut. It achieves this by using the same color encoding method as YCbCr but permits values in the signaling that exceed the range of the BT.601 or BT.709 color spaces.
You might also want to convert HSI color space to these formats:
HSI to HEX converterHSI to RGB(sRGB) converterHSI to CMYK converterHSI to CMY converterHSI to XYZ(ciexyz,cie1931,XYZ D65) converterHSI to HSL converterHSI to HSV(HSB) converterHSI to HWB converterHSI to xyY(Yxy,yxy) converterHSI to YIQ converterHSI to YUV(EBU) converterHSI to YDbDr converterHSI to YCgCo converterHSI to YPbPr(Y/PB/PR,YPRPB,PRPBY,PBPRY,Y/Pb/Pr,YPrPb,PrPbY,PbPrY,Y/R-Y/B-Y,Y(R-Y)(B-Y),R-Y,B-Y) converterHSI to YCbCr(YCC) converterHSI to YcCbcCrc converterHSI to UCS(cie1960) converterHSI to UVW(cieuvw,cie1964) converterHSI to JPEG converterHSI to LAB(cielab) converterHSI to LABh(hunter-lab,hlab) converterHSI to lms converterHSI to LCHab(cielch,LCH,HLC,LSH) converterHSI to LUV(cieluv,cie1976) converterHSI to LCHuv(cielchuv) converterHSI to HSLuv(HuSL) converterHSI to HPLuv(HuSLp) converterHSI to Coloroid(ATV) converterHSI to HCG(HSG) converterHSI to HCY converterHSI to TSL converterHSI to yes converterHSI to OSA-UCS converterHSI to HSP converterHSI to Adobe® 98 RGB compatible converterHSI to Linear Adobe® 98 RGB compatible converterHSI to ACEScc converterHSI to ACEScg converterHSI to ICTCP converterHSI to JzCzHz converterHSI to Jzazbz converterHSI to LCH converterHSI to Lab D65 converterHSI to Oklch converterHSI to Oklab converterHSI to P3 converterHSI to Linear P3 converterHSI to ProPhoto RGB converterHSI to Linear ProPhoto RGB converterHSI to REC.2020 converterHSI to Linear REC.2020 converterHSI to REC.2100-HLG converterHSI to REC.2100-PQ converterHSI to Absolute XYZ D65 converterHSI to XYZ D50 converterHSI to Linear sRGB converterHSI to DLCH(DIN99 LCH) converterHSI to DIN99 Lab(DLAB) converterHSI to OKHSL converterHSI to OKHSV converterHSI to XYB converterHSI to CubeHelix converter