Panel Technology - TN, IPS, VA, & OLED

Liquid crystal displays more or less fall into three categories based on their manufacturer and the driving force behind the liquid crystal. All have their own strengths and weaknesses. Twisted nematic, or TN as it’s often called, is an older display technology. Later, In-Plane Switching, or IPS displays, were developed to combat some of the problems with TN, and a third major technology is the Vertical Aligned, or VA panel.

All LCDs are pretty much built the same, with a backlight, two polarizers, the liquid crystal, and the thin-film transistor which provides the current to the individual pixels. The major difference between the three display types is how the liquid crystal is used to block the backlight for each subpixel.

Generally, laptop displays refresh the image sixty times per second, or at 60 Hertz. Some gaming laptops offer refresh rates at 144 Hz or more, which provide a smoother experience, and both AMD and NVIDIA support variable refresh rates as well. The maximum refresh rate is impacted by the design of the LCD, and the various designs all have different limits and response times.

Twisted Nematic

Twisted nematic, or TN, is the earliest LCD design that’s still used in laptop displays. As the name suggests, the liquid crystal actually twists to allow light through. The design is very simple, with only a single transistor required to drive the process, and therefore it’s the least expensive display to manufacture as well. In addition to it being the lowest cost, it also can operate very quickly, so the TN display is still the panel of choice for many gamers because the panels can hit the high refresh rates like 144 Hz.

Image Source: Japan Display Inc.

While cost and speed are definite advantages of TN, they suffer from quite severe off-angle color shift and are really only usable when viewed directly. Large TN panels can exhibit the color shift even when viewed directly, because of the increasing angle of viewing (relative to the user) as the panel gets further from the center. Even when viewed directly, TN panels offer poor color accuracy as well. Due to these limitations, TN displays have fallen out of favor for most laptops, although they are still regrettably found in some budget devices, and gaming laptops where the higher refresh rate is of more importance than color reproduction.

In-Plane Switching

In-plane switching, or IPS, was developed to provide solutions to the off-angle viewing issues that plague TN displays. The liquid crystal rotates horizontally rather than twisting like a spring in TN, allowing more light through the further it’s rotated, which in turn varies with the amount of voltage applied. This process requires two transistors per subpixel though, which drives up the manufacturing cost. IPS displays are not as quick to operate as a TN one would be either, so driving them to very high refresh rates is difficult. But, this design does offer excellent off-angle viewing, as well as very accurate color reproduction.

Image Source: Japan Display Inc.

And while IPS is a significant step up in quality over TN, it does have some limitations of its own. In particular, it can’t produce the highest contrast ratios, especially compared to Vertical Aligned panels that we’ll look at next. But IPS displays offer the widest viewing angle of any display technology, and keep their color accuracy intact even when viewed at an angle. This makes them ideal for laptops and tablets, and pretty much all quality laptops utilize IPS displays at this point, although this really only started in earnest in the last several years.

Although IPS is the generic class, several manufacturers have created their own version of IPS, such as Samsung’s Plane to Line Switching (PLS) or AU Optronics with their Advanced Hyper-Viewing Angle (AHVA) technology, which by the acronym sounds like it is a VA panel, but it’s actually an IPS design.

Vertical Alignment

The final display LCD display technology that is prevalent in the industry is the vertical alignment, or VA, panel. VA aligns the liquid crystal vertically when no voltage is applied, and with voltage, the crystals shift to the horizontal plane. This mechanism does have some drawbacks to viewing angles, but to counteract this, most VA panels use multi-domain vertical alignment (MVA) with the crystals rotating in different directions.

Image Source: Tom's Hardware Guide

The biggest advantage of VA displays is their contrast ratio capabilities, and modern VA panels can achieve 3000:1 or more contrast. With MVA technology the off-angle viewing is also much better than TN displays, although not as good as IPS displays, and where an IPS display can achieve 178° viewing angles on both the horizontal and vertical planes, a VA panel is going to be around 160° or so depending on the exact type of panel.

The main disadvantage of VA panels is the very slow response time, especially in the gray-to-gray.

VA panels can be found in some computer monitors, but most laptops utilize IPS because the strengths are more suitable to a portable device. VA is still widely used in televisions though, since you generally don’t view them at a very oblique angle, and the increased contrast ratio provides better black levels for movies.

Organic Light Emitting Diode

The final display technology that is available in laptops is organic light emitting diode, or OLED. Unlike all the LCD displays, OLED doesn’t require a backlight because the individual subpixels emit light. Because of this, OLED displays offer practically infinite contrast ratio, since the brightness of each subpixel can be varied on a subpixel-by-subpixel basis, and subpixels can be turned off completely.

OLED displays have been used quite a bit in smartphones, and you can even buy OLED televisions, but the technology has not been utilized very much in the PC space.

Although OLED displays offer a lot of advantages over LCD displays, OLED with an RGB (Red Green Blue) matrix of subpixels (aka RGB OLED) is quite expensive to build, especially on a larger panel. The amazing contrast and accurate color reproduction is a benefit, but the cost can be prohibitive. OLED also doesn’t use any power to display a black screen, but to get high brightness levels on a large panel showing a white image can use substantially more energy than a comparable LCD.

Microscopic view of the ThinkPad X1 Yoga OLED Display subpixel arrangement

Besides price, the other notable drawback to OLED is that the nature of the technology can limit the longevity of the display. As the subpixels are used to create light in either red, green, or blue, the subpixels themselves age and will dim over time. The different colors also age at different rates – with blue being the fastest to go – and to compensate, the subpixels may not be arranged in a true RGB pattern which can reduce the effective resolution of the device. Because of the different rates, there’s also a chance of burn-in if a static image is left on the display for a long period of time, a problem which in turn can be mitigated, though not entirely.

Currently televisions that use OLED are almost exclusively built on a different technology than what you’d see in smartphones and laptops. Right now, LG owns the OLED TV market and produces panels for everyone else using WOLED, which is a white OLED subpixel that is paired with color filters to convert said subpixels to red, green, or blue subpixels. This allows the panels to be manufactured for a cost that people can actually afford, and partially mitigates burn-in since all subpixels have a similar life-expectancy curve. However WOLED subpixels will still age faster or slower depending on how heavily they're used, so burn-in can still be an issue.

Samsung is reportedly looking into something similar, but will use a blue OLED as the base and quantum dots as the filter/converter. But neither of these technologies are used in laptops at the moment, so when you see an OLED TV for several thousand, and wonder why an OLED PC monitor is double the cost for a quarter the size, just know that all things are not created equally.

OLED also can have an issue with ghosting as well, although inserting black frames in between images can reduce that effect.

Due to the cost, high power usage, and aging issues, OLED is currently not ideal for use in laptops, and although it can be stunning to see in a laptop, it does have its drawbacks.

Introduction Building the Transistors and Lighting the Display


View All Comments

  • madskills42001 - Tuesday, July 17, 2018 - link

    Given that contrast is the most important factor in subjective image quality tests, why is more discussion not given to it in this article? Reply
  • s.yu - Saturday, July 21, 2018 - link mention about what non-PWM screens use for dimming? Or do high frequency PWM screens don't count as PWM? And a lot of people seem to be complaining in particular PWM of OLED screens, so why do OLED screens (at least the RGB variety) all use low frequency controllers? Reply
  • Solandri - Saturday, July 28, 2018 - link

    Very nice article. Some minor corrections/additions. (I'll post one at a time since the site is flagging it as spam)

    Light from our sun is actually about 5800K. 6500K is the combination of sunlight and blue sky on a sunny day. It's bluer than direct sunlight because part of the red light gets scattered by the atmosphere (and sent to regions experiencing sunrise/sunset). Daylight in the shade (lit mainly by the blue sky) is closer to 9000K. That combined with the 5800K direct sunlight produces about 6500K.
  • Solandri - Saturday, July 28, 2018 - link

    Non-RGB subpixel arrangements can offer the same viewing experience as RGB while using fewer pixels. Your eyes have the best resolution in green, not so good in red, and absolutely terrible in blue. The non-RGB subpixel layouts take advantage of this, usually by using two green subpixels for each red and blue subpixel. This results in fewer total subpixels (a "lower" resolution), but no discernible loss of resolution to your eye. Older video standards like NTSC and even newer image encoding algorithms like JPEG and MPEG do the same thing to reduce storage space by decreasing the color resolution. So this isn't something new - every TV show you've viewed growing up had its colors mangled this way, and you've never noticed it. So it's silly to suddenly pretend that non-RGB is suddenly inferior. Reply
  • Solandri - Saturday, July 28, 2018 - link

    Ah, it was the website link for this which was flagging the comment as spam. Google "your eyes suck at blue" and you'll get the site with a graphical example of how you can completely mangle the blue channel and the picture will still look the same. Reply
  • Solandri - Saturday, July 28, 2018 - link

    The oddball RGB subpixel layout often used in OLED panels can actually be better for devices which are meant to be used in both portrait and landscape orientation. The RGB subpixels are usually arranged so the relative position of red, green, and blue are the same when rotated 90 degrees (though there might be a shift of one subpixel). In contrast, the traditional RGB stripe layout is completely different when rotated 90 degrees.

    Keeping the subpixel layout the same in both orientations allows you to do subpixel rendering in both orientations. Subpiexl rendering improves the apparent resolution of the screen without increasing the actual resolution. So if you're rendering a diagonal white line, instead of rendering it as (capital letters are lit, lowercase are black):


    You render it as


    And you've tripled the screen's apparent resolution without adding any new pixels. This trick is most often used with fonts (ClearType in Windows). But the RGB subpixel layout means apparent resolution can only be increased in one direction, and fonts designed for subpixel rendering will only work in one screen orientation. If you rotate the screen 90 degrees, suddenly the subpixels don't fall the way you expect, and your subpixel rendering breaks. Not so with the subpixel layout used in some OLED screens. If you turn the screen 90 degrees, the RGB layout remains the same, and your subpixel rendering still works.
  • Solandri - Saturday, July 28, 2018 - link

    You forgot to mention the RGBW subpixel layout, which I wish would die but keeps coming back. That's where they add a white subpixel to increase the apparent brightness of the screen. The R, G, and B subpixels generate those colors by blocking 66% of the light. So when you display a white pixel (R, G, and B lit), you're actually only seeing 33% of the backlight brightness. Someone came up with the idea of adding a white subpixel, so when displaying white you see 3*(33%*25%)+(100%*25%) = 50% of the backlight brightness. So the screen can appear brighter at the same power level, or the laptop will use less power at the same image brightness.

    Unfortunately this comes at the cost of muting colors, since your colors are now only transmitted through 75% of the subpixels instead of 100%. And you end up with pale red, green, blue, and mustard yellows and lavender purples.
  • Solandri - Saturday, July 28, 2018 - link

    The solution many vendors came up with to customers complaining about poor colors is to create a mode where the white subpixel is always off. But if you do that, now your whites are generated by only letting 3*(33%*25%)+(100%*0%) = 25% of the backlight through. And now your screen will either be dimmer than RGB, or will use more power when at the same brightness as RGB. In other words, you've defeated the purpose of using RGBW subpixels in the first place. If you see a review mention the screen is RGBW, that's a big red flag and should be avoided. Reply
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