List Of Color Spaces And Their Uses - Wikipedia

This is a list of color spaces, grouped by the color model that is used for part of their specification.

Models

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Color models can be based on physics or human perception. Physical descriptions of color can be additive (describes mixing of light, RGB) or subtractive (describes mixing of pigment or removal of light, CMYK). Descriptions based on human perception are based on some experimental results on humans. Some models and their variants are employed in parts of the color spaces listed below.[1]

Human perception

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Instead of being based on color mixture, they are based on human experience or phenomenology.

CIE 1931 XYZ

[edit] Main article: CIE 1931 color space

CIE 1931 XYZ was the first attempt to produce a color space based on measurements of human color perception and the basis for almost all other color spaces.

CIEUVW

[edit] Main article: CIE 1964 color space

Measurements over a larger field of view than the "CIE 1931 XYZ" color space which produces slightly different results.

Uniform color spaces

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Uniform color spaces (UCSs) are built such that the same geometrical distance anywhere in the color space reflects the same amount of perceived color difference. There have been many attempts at building such a color space.

As human vision has three components, the space is necessarily 3D; it is generally assigned such that one is the lightness and the other two the chroma. A uniform color space is useful for a wide range of tasks. It can be used to calculate color difference or to pick colors in a visually harmonious way, for example.

CIELUV

[edit] Main article: CIELUV

A modification of "CIE 1931 XYZ" to display color differences more conveniently. The CIELUV space is useful for additive mixtures of lights, due to its linear addition properties (human hue perception does not respect light addition, however).[2]

CIELAB

[edit] Main article: CIELAB color space

CIELAB produces a color space that is more perceptually linear than other color spaces. Perceptually linear means that a change of the same amount in a color value should produce a change of about the same visual importance. CIELAB has almost entirely replaced an alternative related Lab color space called “Hunter Lab”. This space is commonly used for surface colors, but not for mixtures of (transmitted) light.[2]

HSLuv

[edit] Main article: HSLuv

HSLuv preserves the lightness and hue components of CIELUV LCh and stretches its chroma so that every color has the same range, defined as a percentage.

Newer models

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CIELAB and CIELUV are soon recognized to be insufficient to explain the entire range of color phenomena. A range of increasingly complex color appearance models appeared to model the behavior of human vision under different viewing conditions, but ended up less used due to the added inputs required and overall algorithmic complexity.

In addition, the performance of the 1976 color spaces under different viewing conditions is not their only problem. Even under the default reference viewing condition, CIELAB is known to poorly work in blue hues. For a standard dynamic range and a fixed viewing condition, it turns out that CIELAB's simple structure suffices as long as better coefficients are used.

The IPT color space of 1998 uses new data about hue to greatly improve on CIELAB's non-constant lines of hue,[3] although it still leaves much to be desired in its prediction of colorfulness and lightness. Oklab[4][5] uses IPT data for hue and a modern CAM (CAM16) to generate lightness and colorfulness data, resulting in an improved fit over human perception under the same structure.[6]

RGB primaries

[edit] Main articles: RGB color model and RGB color spaces

RGB (red, green, blue) describes the chromaticity component of a given color, when excluding luminance. RGB itself is not a color space, it is a color model. There are many different color spaces that employ this color model to describe their chromaticities because the R/G/B chromaticities are one facet for reproducing color in CRT & LED displays.

sRGB

[edit] Main article: sRGB

The sRGB color space (standard red, green, blue) was created jointly by Hewlett-Packard and Microsoft for use on the Internet. It has been endorsed by the W3C, Exif, Intel, Pantone, Corel, and many other industry players. It is also well accepted by open-source software such as the GIMP, and is used in proprietary and open graphics file formats such as SVG.

sRGB is intended as a common color space for the creation of images for viewing on the Internet and World Wide Web (WWW). The resultant color space closely approximates a Gamma correction of 2.2,[7] the average response of a CRT display to linear voltage levels.

Adobe RGB

[edit] Main article: Adobe RGB color space

The Adobe RGB color space was developed by Adobe Systems in 1998. It was designed to encompass most of the colors achievable on CMYK color printers, but by using RGB primary chromaticities on a device such as the computer display. The Adobe RGB color space encompasses roughly 50% of the visible colors specified by the Lab color space, improving upon the gamut of the sRGB color space primarily in cyan-greens.

Adobe Wide Gamut RGB

[edit] Main article: Wide-gamut RGB color space

The Adobe Wide Gamut RGB color space was developed by Adobe Systems as an alternative to the standard sRGB color space. It is able to store a wider range of color values than sRGB. The Wide Gamut color space is an expanded version of the Adobe RGB color space, developed in 1998. As a comparison, the Adobe Wide Gamut RGB color space encompasses 77.6% of the visible colors specified by the Lab color space, whilst the standard Adobe RGB color space covers just 50.6%.

One of the downsides to this color space is that approximately 8% of the colors representable are imaginary colors that do not exist and are not representable in any medium.[8] This means that potential color accuracy is wasted by reserving these unnecessary colors.

Rec. 2100

[edit] Main article: Rec. 2100

Rec. 2100 is a color space standardized by ITU and used for HDR-TV. It has a peak luminance of at least 1,000 cd/m2[9] (higher than the 100 cd/m2 limit of SDR and color spaces such as Rec. 709 and Rec. 2020).[10][11][12] It uses a non-gamma transfer function (PQ or HLG) and system colorimetry (chromaticity of color primaries and white point) identical to Rec. 2020 system colorimetry.[9]

Others with RGB primaries

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• ProPhoto RGB color space
• scRGB
• DCI-P3, used primarily for digital movie projection
• SMPTE 240M / SMPTE "C", used in NTSC and MUSE analog television systems
• Rec. 601, used for SDTV
• Rec. 709, used for HDTV[11]
• Rec. 2020, used for UHDTV[12]
• Academy Color Encoding System (ACES)

YCbCr and YUV

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The analogue YUV and digital YCbCr refer to a variety of linear methods to try to separate lightness from chroma signals in an RGB input using linear combination. As the input RGB values are gamma-corrected, such a separation does not truly produce lightness and two chroma signals, but a "luma" signal and two "chrominance" signals instead.

YUV: as human eyes have lower resolution in their color perception, it is more economic to put more of the bandwidth in encoding Luma. The same principle is used in YCC. In YCC, separating also has the added benefit of removing most of the correlation between the input channels, therefore providing better compression.

YCoCg is a version of YCbCr with extremely simple coefficients. It results in faster computation, lossless conversion, and apparently better decorrelation.

ICtCp is used similarly to YCC in video compression, but is more appropriately described as a high dynamic range uniform color space.

Other similar color spaces:

• YPbPr
• YDbDr
• YIQ
• xvYCC
• sYCC

Cylindrical transformations

[edit] See also: Color model § Cylindrical-coordinate color models

Cylindrical transformations seek to turn a color model into three components: the lightness, the colorfulness, and the hue.

HSV and HSL

[edit] Main article: HSL and HSV

HSV and HSL are transformations of Cartesian RGB primaries (usually sRGB), and their components and colorimetry are relative to the colorspace from which they are derived. HSV (hue, saturation, value), also known as HSB (hue, saturation, brightness), is often used by artists because it is often more natural to think about a color in terms of hue and saturation than in terms of additive or subtractive color components. HSL (hue, saturation, lightness or luminance), also known as HSI (hue, saturation, intensity) or HSD (hue, saturation, darkness), is quite similar to HSV, with "lightness" replacing "brightness". The difference is that a perfectly light color in HSL is pure white; but a perfectly bright color in HSV is analogous to shining a white light on a colored object. I.e. shining a bright white light on a red object causes the object to still appear red, just brighter and more intense. Shining a dim light on a red object causes the object to appear darker and less bright.

The issue with both HSV and HSL is that these approaches do not effectively separate colour into their three value components according to human perception of color.[citation needed] This can be seen when the saturation settings are altered — it is quite easy to notice the difference in perceptual lightness despite the "V" or "L" setting being fixed.

LCh: uniform color space

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For uniform color spaces that already have a lightness component, the transformation only involves rearranging the two chroma values into colorfulness (C) and hue (h).

CIELChab and CIELChuv are cylindrical transformations of the CIELAB and CIELUV color spaces, respectively. The cylindrical coordinates C* (chroma, relative saturation) and h° (hue angle, angle of the hue in the color wheel) are specified. The CIELAB and CIELUV coordinate L* (lightness) remains unchanged.

The newer UCS systems can also be applied to a similar transform. In fact, both IPT and Oklab/Oklch are designed for hue uniformity, a feature that is only explicitly shown after a cylindrical transformation.

Subtractive

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CMYK and CMY

[edit] Main articles: CMYK color model and CMY color model

CMYK is used in the printing process, because it describes what kinds of inks are needed to be applied so the light reflected from the substrate and through the inks produces a given color. One starts with a white substrate (canvas, page, etc.), and uses ink to subtract color from white to create an image. CMYK stores ink values for cyan, magenta, yellow and black. There are many CMYK colorspaces for different sets of inks, substrates, and press characteristics (which change the dot gain or transfer function for each ink and thus change the appearance).

Commercial color spaces

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• Munsell color system – early perceptually-uniform color space
• Natural Color System (NCS) – perceptual
• Pantone Matching System (PMS) – standardized color reproduction (and color list)
• Spot Matching System (SMS) - 3C (Cross-media, Colour Consistent) Colour Palettes for CMYK and Extended gamut printing, web design and television graphics.
• RAL – standardized color matching (and color list)
• Aerospace Material Specification – Standard 595A (Supersedes (US) Federal Standard 595C)[13]
• (US) Federal Standard 595C
• British Standard Colour (BS)
• HKS – standardized color reproduction (and color list)
• HLC Colour Atlas – a free and open-source color space (and color list) based on CIELab[14]

Special-purpose color spaces

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• The rg chromaticity space is used in computer vision applications, and shows the color of light (red, yellow, green, etc.), but not its intensity (dark, bright).
• LMS color space (long, medium, short), a perceptual color space based on the response functions of the cones in the retina of the eye. It is mostly used in psychophysical research.
• TSL color space is used in face and skin detection.

Obsolete color spaces

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Early color spaces had two components. They largely ignored blue light because the added complexity of a three-component process provided only a marginal increase in fidelity when compared to the jump from monochrome to two-component color.

• RG for early Technicolor film
• RGK for early color printing

References

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1. ^ Gravesen, Jens (November 2015). "The Metric of Color Space" (PDF). Graphical Models. 82: 77–86. doi:10.1016/j.gmod.2015.06.005. S2CID 33425148. Retrieved 28 November 2023.
2. ^ a b Keith McLaren; "Dyes, General Survey" in: Ullmann's Encyclopedia of Industrial Chemistry; Wiley-VCH; 15 June 2000.
3. ^ Ebner; Fairchild (1998), Development and Testing of a Color Space with Improved Hue Uniformity, Proc. IS&T 6th Color Imaging Conference, Scottsdale, AZ, pp. 8–13{{citation}}: CS1 maint: location missing publisher (link)
4. ^ Ottosson, Björn (2020-12-23), A perceptual color space for image processing, retrieved 2021-01-18
5. ^ "OKLab and OKLCH". CSS Color Module Level 4 (Working draft). World Wide Web Consortium. Retrieved 17 January 2022.
6. ^ Ottosson, Björn (23 December 2020). "A perceptual color space for image processing".
7. ^ "The Importance of Terminology and sRGB Uncertainty". Colour Science. 5 December 2015. Retrieved 11 January 2023.
8. ^ "Welcome to Bruce Lindbloom's Web Site".
9. ^ a b "BT.2100 : Image parameter values for high dynamic range television for use in production and international programme exchange". www.itu.int. Retrieved 2021-02-11.
10. ^ "BT.1886 : Reference electro-optical transfer function for flat panel displays used in HDTV studio production". www.itu.int. Retrieved 2021-02-11.
11. ^ a b "BT.709 : Parameter values for the HDTV standards for production and international programme exchange". www.itu.int. Retrieved 2021-02-11.
12. ^ a b "BT.2020 : Parameter values for ultra-high definition television systems for production and international programme exchange". www.itu.int. Retrieved 2021-02-11.
13. ^ "AMS STANDARD 595A COLOR". www.ams-std-595-color.com. SAE and Harzen. Retrieved 12 July 2019.
14. ^ "HLC Colour Atlas". freiefarbe.de. freieFarbe e.V. Retrieved 18 January 2025.

External links

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• Precise Color Communication—Konica Minolta Sensing

v t e Color space
List of color spaces Color models
CAM	CIECAM02 iCAM CAM16 CIECAM16
CIE	XYZ (1931) RGB (1931) YUV (1960) UVW (1964) CIELAB (1976) CIELUV (1976) CIECAM02 CIECAM16
RGB	RGB color spaces sRGB rg chromaticity Adobe Wide-gamut ProPhoto scRGB DCI-P3 Rec. 601 SMPTE 240M/"C" Rec. 709 Rec. 2020 Rec. 2100
Y′UV	YUV PAL YDbDr SECAM YIQ NTSC YCbCr Rec. 601 Rec. 709 Rec. 2020 Rec. 2100 ICtCp Rec. 2100 YPbPr MAC xvYCC YCoCg
Other	CcMmYK CMYK ColorADD Coloroid LMS Hexachrome HSL, HSV HCL Imaginary color Oklab OSA-UCS PCCS RG RYB HWB YJK TSL
Color systemsand standards	ACES ANPA Colour Index International CI list of dyes DIC Federal Standard 595 HKS ICC profile ISCC–NBS Munsell NCS Ostwald Pantone RAL list JIS Z8102 [ja]
For the vision capacities of organisms or machines, see  Color vision.

v t e Color topics
Color science	Color physics Electromagnetic spectrum Light Rainbow Visible Spectral colors Chromophore Structural coloration Animal coloration Color of chemicals Water Spectral power distribution Colorimetry Color perception Chromesthesia Sonochromatism Color blindness Achromatopsia Dichromacy Color calibration Color constancy Color task Color code Color temperature Color vision test Evolution of color vision Impossible colors Metamerism Opponent process Afterimage Unique hues Tetrachromacy The dress Color psychology Color symbolism Color preferences Lüscher color test Kruithof curve Political color National colors Chromophobia Chromotherapy Color reproduction Color photography Color balance Color cast Digital image processing Color management Color printing Multi-primary color display Quattron Color model additive RGB subtractive CMYK Color space Image color transfer
Colorphilosophy	Color scheme Color tool Monochromatic colors Black and white Grisaille Complementary colors Analogous colors Achromatic colors (Neutral) Polychromatic colors Light-on-dark Web colors Tinctures in heraldry Color theory Color mixing Primary color Secondary color Chromaticity Color solid Color wheel Color triangle Color analysis (fashion) Color realism (art style) On Vision and Colours (Schopenhauer) Theory of Colours (Goethe)
Color terms	Basic English terms Red Orange Yellow Green Blue Purple Pink Brown White Gray Black Cultural differences Linguistic relativity and the color naming debate Blue–green distinction in language Color history Black-and-white dualism Blue in culture Color in Chinese culture Traditional colors of Japan Human skin color Color dimensions Hue Dichromatism Colorfulness Pastel colors Luminance Lightness Darkness Brightness Iridescence Fluorescence Grayscale Tint, shade and tone
Colororganizations	Pantone Color Marketing Group Color Association of the United States International Colour Authority International Commission on Illumination (CIE) International Color Consortium International Colour Association
Names	Lists Alphabetical List of colors: A–F G–M N–Z Full list List of colors by shade List of color palettes List of color spaces List of Crayola crayon colors history Color chart List of RAL colors List of web colors Shades of: Red Orange Yellow Green Cyan Blue Violet Purple Magenta Pink Brown White Gray Black
Related	Vision Contrast Qualia Lighting
Category Index