Summary

Every modern flat panel display consists of physical “pixels” or “picture elements” that make up the image as a whole. Pixels are already tiny, but each one is a complex machine in its own right, with numerous independent parts.

There are different ways to put together a display at the subpixel level, and these tiny differences can have significant effects on how your screen looks and performs. So let’s cover the basics of subpixels, and how they might influence your next gadget purchase.

Subpixels from an iPad Pro mini LED just visible at high magnification.

What Are Subpixels?

A pixel is the smallest component of a digital image. Each pixel has a color value, and so when you set the color of each one just right, you get a reproduction of the original image.

The physical pixels in a flat panel display have subcomponents known as subpixels. Typically, but not always, there are three subpixels. One for red, one for green, and one for blue. The predecessor to flat panel displays, CRT screens, used three electron beams instead, corresponding to each color.

Samsung Neo QLED 8K TV at CES 2024

By adjusting the intensity of each subpixel, you’re able to recreate just about any color. This is why you can sample a color from a digital image and get its RGB value. These are literally the numerical values for each subpixel.

How Subpixels Affect Display Quality

There are a few different ways to construct and arrange subpixels and this subpixel structure affects how sharp or color-accurate a display is, as well as how much it costs to make.

Resolution and Sharpness

A great example of how much subpixel structure matters is thepentilesubpixel arrangement. While you’d usually expect each pixel to have its own set of three subpixels in a standard RGB arrangement, pentile displays actually share subpixels between pixels. For example, you may have two green and two red subpixels for each blue subpixel. The main advantage of this is that you can pack more pixels into a small space, which is why most mobile phone screens use this arrangement.

Pentile displays work because of how our eyes perceive red, blue, and green light differently. In short, we have significantly fewer cone cells for blue light than red or green, and so reducing the number of blue subpixels doesn’t really degrade the image, or our perception of how bright and vibrant it is. Pentile displays do have some issues with color “leakage” or image distortion that needs to be compensated for, but is less apparent on a 6-inch screen. The pixels from the image are “subsampled” onto “logical” pixels in the display that are either centered on a green or red subpixel, and these neighboring logical pixels share blue subpixels.

Subpixel rendering of text on an LCD.

Color Accuracy

Some subpixel structures add a fourth subpixel. This is usually either a white (RGBW) or yellow (RGBY) subpixel. These subpixels can help enhance the brightness of the display, or how wide the color gamut is.

However, it’s not only the number and type of subpixels that matter, but also how they are arranged. Some arrangements can cause color fringing, or affect viewing angles.

Viewing Angles and Uniformity

The way subpixels are aligned impacts how a display looks from different angles. Technologies like IPS (In-Plane Switching) use a specific subpixel arrangement that allows for better viewing angles compared to TN (Twisted Nematic) panels, which may shift in color when viewed from the side.

One good example is Samsung’s “dual pixel” layout in its QLED TVs, which splits a pixel into two domains and drives them slightly differently to improve the viewing angles of the display. Something that’s pretty important in a TV compared to a monitor.

Text Rendering and Clarity

Text clarity is also influenced by subpixel rendering techniques like ClearType (Windows) and Subpixel Anti-Aliasing (in macOS before Mojave). These methods take advantage of the human eye’s perception of color to smooth out text edges, making it more readable on LCD screens. This is why ClearType only works properly on an LCD and not on a CRT, because it compensates for the specific pixel geometry of that display technology. With modern displays that have extremely high pixel densities (e.g. Apple’s Retina Displays) this isn’t necessary anymore since the pixels are so tiny.

Subpixels and Display Technologies

Different display technologies use subpixel geometry in unique ways to optimize for the strength of that technology:

Why Subpixels Matter to You

So this is all interesting for display nerds, but what does it matter to the average person? The long and short of it is that if you’re looking to buy a new monitor, TV, or device with a screen, it’s worth looking up what the subpixel geometry of that device is. This can help you understand if you’re going to face specific shortcomings or advantages in that device.

For example, some people simply don’t like how some of Samsung’s past pentile phone displays looked, and that was enough reason to avoid them and go for something else. It also helps you understand why OLED or microLED technology can outperform backlit LCD displays, or why QLEDs manage such good color vibrancy.

If you want to dig into all the different subpixel layouts. I suggest checking out Geometrian’sSubpixel Zoo, which has numerous excellent microscopic photos of pixel layouts along with the pros and cons of each.