primary colours of light
Category: Science & Tech
- Key People:
- Piet Mondrian
primary colour, any of a set of colours that can be used to mix a wide range of hues. There are three commonly used primary colour models: RGB (red, green, and blue), CMY (cyan, magenta, and yellow), and RYB (red, yellow, and blue). The colour variations between the models are due to the differences between additive and subtractive colour mixing.
Additive colour mixing
Additive colour mixing occurs when two or more colours, created through light waves, are combined before they reach the eye. This can be visualized by shining coloured lights onto a white wall. If red and green beams of light are combined in equal amounts, they create the colour yellow (in this case, yellow is a secondary colour—the result of a mixture of two primary colours—but in the subtractive CMY and RYB colour models, yellow serves as a primary colour). If a more saturated red beam is mixed with the same green beam, then the resulting light would be the colour orange.
The scientific basis of additive colour mixing comes from English physicist and mathematician Isaac Newton’s 1665 and 1666 experiments with light—specifically, the test in which he separated white light with a glass prism. Newton determined in his book Opticks (1704) that white light is a combination of all colours, which he listed as red, orange, yellow, green, blue, indigo, and violet. In the early 19th century, the mixing of coloured light was explored by English physicist Thomas Young, who theorized that the human eye perceives colour through three photoreceptors that are only sensitive to specific wavelengths on the visible spectrum. About 50 years later, German physicist Hermann von Helmholtz built upon Young’s theory and suggested that each of the three receptors could only receive short, medium, or long wavelengths.
The RGB colour model (red, green, and blue) was initially demonstrated in 1861 by Scottish mathematician and physicist James Clerk Maxwell in his projection of what is often called the first colour photograph. Using knowledge built from previous experiments with multicoloured spinning tops, Maxwell had British photographer Thomas Sutton take three black-and-white photographs of the same object—once each with red, green, and blue filters placed over the lens—which were printed on glass and projected together.
The RGB colour model also aligns with Helmholtz’s wavelength theory, with red, green, and blue as long, medium, and short wavelengths, respectively. When mixed with different combinations and ratios, these primary colours form a wide range of hues, and, when equal amounts of red, green, and blue light are combined, they form white light. The RGB colour model is used in digital devices, such as televisions and computers.
Subtractive colour mixing
When using subtractive colour mixing, the colourants absorb and selectively transmit or reflect light. This can be seen when a coloured filter is placed over a beam of light. If a yellow filter is used, all other colours are absorbed, leaving only yellow light shining through. It is also seen in paints and other pigments. Yellow paint absorbs blue and violet light while reflecting yellow light, as well as green and red light which combine to create more yellow light.
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When a different colour, such as blue—which absorbs yellow, orange, and red light—is mixed with yellow, the result is the coloured light that was not absorbed by either pigment. In the case of blue and yellow, the result would be green. As more pigments are combined, more light is absorbed, and the colour mixture progressively becomes darker.
The CMY colour model (cyan, magenta, and yellow) aligns with the additive primary colours of red, green, and blue. Cyan absorbs red light, magenta absorbs green light, and yellow absorbs blue light. This colour set, with the addition of black, is often used when printing images.
Although red, yellow, and blue (the RYB colour model) are widely taught as main primary colours, the CMY colour model produces a larger range of colour mixtures. The RYB colour model is the oldest and perhaps most accessible of the three colour models, having likely been known since ancient times by artists working inpaint and easily taught and visualized with art supplies in a classroom. The RYB and CMY colour models have often been conflated due to the misconception that cyan is equivalent to blue and that magenta is equivalent to red.
Another common misconception is that primary colours are “pure” and cannot be made by mixing other pigments. In reality, colours from the CMY model can be created from colours from the RYB model and vice versa. The RYB primary colour red can be made by combining magenta and yellow pigments, and the CMY primary colour magenta can be made by combining red and blue.
As an enthusiast with a deep understanding of the topic, I've delved into the intricacies of color theory, specifically the primary colors of light. My expertise extends to the historical foundations, scientific principles, and practical applications of color models such as RGB, CMY, and RYB. Let's explore the concepts used in the provided article.
The article begins by introducing the concept of primary colors of light, emphasizing their role in mixing a wide range of hues. Three commonly used primary color models are mentioned: RGB (red, green, and blue), CMY (cyan, magenta, and yellow), and RYB (red, yellow, and blue).
Additive color mixing is explained as the process of combining colors created through light waves before reaching the eye. The variations between color models arise from the differences between additive and subtractive color mixing. The article provides a practical example: combining red and green light to create yellow, and how the saturation of colors influences the resulting mixture.
Isaac Newton's foundational experiments with light in the 17th century are highlighted, particularly his use of a glass prism to separate white light into its constituent colors. Thomas Young's theory of three photoreceptors sensitive to specific wavelengths and Hermann von Helmholtz's elaboration on this theory are also discussed. The RGB color model, aligned with Helmholtz's wavelength theory, is credited to James Clerk Maxwell in 1861, who demonstrated it with the first color photograph.
Subtractive color mixing is then introduced, where colorants absorb and selectively transmit or reflect light. The article explains this using the example of a colored filter absorbing certain colors and letting others through. In the case of paints and pigments, the absorption and reflection of light are applied to create different colors.
The CMY color model aligns with the additive primary colors of RGB, with cyan absorbing red light, magenta absorbing green light, and yellow absorbing blue light. This model, along with black, is commonly used in image printing.
The article also addresses common misconceptions, such as the conflation of RYB and CMY models, and the misconception that primary colors are "pure" and cannot be created by mixing other pigments. It clarifies that colors from the CMY model can be created from colors in the RYB model and vice versa.
In conclusion, the provided information covers the historical context, scientific principles, and practical applications of primary colors of light, encompassing the RGB, CMY, and RYB color models.
