The Differences Between CMYK and RGB

The Differences Between CMYK and RGB

There are a great many different colour modes available, however the 2 most popular and most important are RGB and CMYK. They are used significantly more than the countless other colour modes as they are the most natural for their respective uses. Both are used widespread and serve their own purposes, as such, it is important to know the differences between them and when to use them so that you can ensure they are properly utilized.

Why Are They Different?

CMYK is the industry standard when it comes to printed materials. It is a subtractive process, meaning the inks subtract from external reflected light in order to create the desired colour. CMYK stands for Cyan, Magenta, Yellow, and Key; the 4 different inks used in the printing process. The key ink is typically representative of black, but is called key as it is used on the key plate in printing process.

Venn diagram depicting how CMYK blends various colours

RGB is the colour mode used primarily for all digital platforms; computers, phones, tablets, televisions and many others all use RGB to create their images. RGB is additive, meaning it adds different colours of light to create the colour it needs. RGB stands for Red, Green, and Blue; the 3 primary lights used to create any other colour. Because RGB displays generate their own light, they are ideal for dark environments where it could be difficult to see.

Venn diagram depicting how RGB blends various colours

What Can They Do?

As mentioned RGB is used for digital screens whereas CMYK is used for printed materials. They are this way due to the nature of their respective technologies. A digital screen requires light to be produced internally to create its image. To do this it uses colour lights; Red, Green, and Blue. In contrast CMYK is printed onto other materials and uses the light from external sources that bounce off it.

To create white RGB uses all 3 colour at full power, whereas black has them all off; any other colours are produced by various combinations. All three of the RGB colours have 256 different levels that can be used to create different colours. There are over 16 million possible colours with RGB; 16 777 216 to be exact.

4 096 x 4 096 image representing all 16 777 216 colours of RGB

Some sources will claim that RGB only has 216 colours, and that is because of what is referred to as web safe colours. Web safe colours are a set of 216 colours that would render the same on all displays. For a long time, although it was possible to produce other colours, these 216 were the only ones used to ensure that it would display correctly. As technology has advanced the need for this has faded as modern monitors and displays can consistently display the full range.

To create black, CMYK can use the key plate alone, but if combined with the other colours different types of black can be made. Pure black, rich black, cool black, warm black, and registration black are just a small handful of the many blacks that are used in CMYK. 

Boxes showing 2 different blacks

Unlike RGB, CMYK is incapable of creating white. The white of CMYK is merely the colour of the paper or material it is being printed on. If you were to print an image onto a coloured sheet of paper, any white in the image would be the colour of the paper; and the image would have a colour cast due the paper being treated as white.

Where RGB has a specified number of colours that can be used, CMYK does not. Theoretically it could produce billions, however in practice this is far from the case. Most printers cannot print more than a couple hundred thousand colours. This is due to the modern technology of printers, as well as limitations on how much ink the material can absorb.

Comparison demonstrating how RGB has a larger colour gamut

How You Should Use Them?

Due to the lower number of colours available, this must be kept in mind when creating files for print. Something created using RGB can come out drastically different when printed. Many programs offer the option to convert RGB to CMYK, or even work entirely in CMYK; however, the only true way to see what a printed product will look like is once it has been printed, as these programs are merely simulating CMYK using RGB.

The best option is typically dependant on what you’re working on. If you are making vector artwork or anything that, when printed, needs to be a very specific colour, it is best to work in CMYK so that that colour will be printed exactly as intended. In many other cases however, it is best to work with RGB. Doing so allows you to better visualize what you are working on. Once you’ve completed your work, it can be converted to the exact printer profile required, guaranteeing the most accurate print out.

RGB simulation of colour saturation lost when converting RGB to CMYK

When an RGB file is sent for printing, it is up to the printer to interpret how it should print those colours. This can lead to unexpected results, whereas when it is properly converted beforehand, you have full control over how it will print. This is important to ensure that the end product is exactly what you are expecting.

A process closely related to CMYK, although rarely used, is CcMmYK which involves using, in addition to the 4 CMYK colours, a light cyan and a light magenta. This is generally only used in situations where very light colour tones are required, as it uses much more ink than regular CMYK.

One thing often used in conjunction with CMYK are Pantones. Pantones are a series of 1 867 unique colours used for printing that all use unique inks. They are used as spot colours, typically for logos as when they are printed they are always the same, regardless of printer or paper type. Although they have CMYK alternatives, they are typically inaccurate or inconsistent, meaning the only way to get the colour of a Pantone is to use a Pantone.

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Example of a box using a pantone

Some print shop will have unique requirements, perhaps wanting a RGB file instead of a CMYK file. It is best to do as they request as they know they their equipment best and will likely be able to produce better results themselves. 

Caidence Payne
caidence@lekac.com
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