In traditional color theory, it is believed that all colors can be mixed from 3 universal primary - or pure - colors, which were originally believed to be red, yellow and blue pigments (representing the RYB color model). However, modern color science does not recognize universal primary colors and only defines primary colors for a given color model or color space. RGB and CMYK color models are popular color models in modern color science, but are only chosen as efficient primaries, in that their combination leads to a large gamut. However, any three primaries can produce a viable color gamut. The RYB model continues to be used and taught as a color model for practical color mixing in the visual arts.
Secondary color
A secondary color is an even mixture of two primary colors. For a given color model, secondary colors have no special meaning, but are useful when comparing additive and subtractive color models.
Intermediate color
An intermediate color is any mixture of a secondary and a primary color. They are often visualized as even mixtures, but intermediate colors can arise from any mixture proportion. Therefore any color that is not a secondary or primary color is an intermediate color.
Tertiary color
Tertiary color has two common, conflicting definitions, depending on context.
In traditional color theory, which applies mostly to practical painting, a tertiary color is an even mixture between two secondary colors, i.e. a mixture of three primaries in 1:2:1 proportion. This definition is used by color theorists, such as Moses Harris[1] and Josef Albers.[2] The result is approximately a less saturated form of the dominant primary color of the mixture. Under this definition, a color model has 3 tertiary colors.
More recently, an alternative definition has emerged that is more applicable to digital media, where a tertiary color is an intermediate color resulting from an even mixture of a primary and a secondary color, i.e. a mixture of the primaries in 3:1:0 proportion. The result yields a maximum saturation for a given hue. Under this definition, a color model has 6 tertiary colors.
Quaternary color
A quaternary color is a seldom-used descriptor that is the conceptual extension of a tertiary color. Quaternary colors have no special use or status in color theory or color science.
Under the traditional definition, a quaternary color is the even mixture of two tertiary colors, as demonstrated by Charles Hayter. These quaternary colors have contributions from all three primaries in 3-3-2 proportions, so are very desaturated (even mixtures of three primaries gives a neutral color: zero saturation). Under this definition, a color model has 3 quaternary colors.
Under the modern definition, a quaternary color is the even mixture of a tertiary color with either a secondary or primary color. Quaternary colors are sometimes given a maximum saturation for their hue. Under this definition, a color model has 12 quaternary colors.
The CMY color model is an analogous subtractive mixing color model, used to estimate the mixing of colored pigments, with primary colors cyan, magenta, and yellow, equivalent to the secondary colors of the RGB color model. The secondary colors of the CMY model are blue, red and green, equivalent to the primary colors of the RGB model, as demonstrated here:
Under the modern definition, the 6 tertiary colors are conceptually equivalent between the color models, and can be described by the even combinations of a primary and a secondary color:
A color model is a conceptual model and does not have specifically defined primary colors. A color space based on the RGB color model, most commonly sRGB, has defined primaries and can be used to visualize the color mixing and yield approximate tertiary colors. Also note that the color terms applied to tertiary and quaternary colors are not well-defined.
sRGB colors approximating primary (1), secondary (2), tertiary (3), and quaternary (4) colors in an RGB color model and additionally defined by the hue angle in HSV color space
RYB is a subtractive mixing color model, used to estimate the mixing of pigments (e.g. paint) in traditional color theory, with primary colors red, yellow, and blue. The secondary colors are green, purple, and orange as demonstrated here:
Under the modern definition (as even combinations of a primary and a secondary color), tertiary colors are typically named by combining the names of the adjacent primary and secondary color.[3][4] However, these tertiary colors have also been ascribed with common names: amber/marigold (yellow-orange), vermilion/cinnabar (red-orange), magenta (red-purple), violet (blue-purple), teal/aqua (blue-green), and chartreuse/lime green (yellow-green). The 6 tertiary colors are given:
Approximate colors and color names are given for the tertiary and quaternary colors. However, the names for the twelve quaternary colors are quite variable, and defined here only as an approximation.
RYB colors approximating primary (1), secondary (2), tertiary (3), and quaternary (4) colors[6]
red (1)
scarlet (4)
vermilion (3)
persimmon (4)
orange (2)
sun (4)
amber (3)
golden (4)
yellow (1)
lemon (4)
chartreuse (3)
lime (4)
green (2)
viridian (4)
teal (3)
cerulean (4)
blue (1)
indigo (4)
violet (3)
amethyst (4)
purple (2)
aubergine (4)
magenta (3)
crimson (4)
red (1)
Under the traditional definition, there are three tertiary colors, approximately named russet (orange–purple), slate (purple–green), and citron (green–orange), with the corresponding three quaternary colors plum (russet–slate), sage (slate–citron), buff (citron–russet) (with olive sometimes used for either slate or citron).[7][8] In every level of mixing, saturation of the resultant decreases and mixing two quaternary colors approaches gray.
The RYB color terminology outlined above and in the color samples shown below is ultimately derived from the 1835 book Chromatography, an analysis of the RYB color wheel by George Field, a chemist who specialized in pigments and dyes.[9]
RYB colors produced by mixing equal amounts of secondary and subsequent colors[6]
^ abRGB approximations of RYB tertiary colors, using cubic interpolation."RYB RGB conversion". Archived from the original on 2013-06-28. Retrieved 2012-12-29. The colors are paler than a simple mixture of paints would produce. Pure tertiary colors would be darker still.
^William J. Miskella, 1928, Practical Color Simplified: A Handbook on Lacquering, Enameling, Coloring And Painting, pp
^John Lemos, 1920, "Color Charts for the School Room", in School Arts, vol. 19, pp 580–584
^Maerz and Paul (1930). A Dictionary of Color. New York. p. 154.{{cite book}}: CS1 maint: location missing publisher (link)