lcd panel types comparison brands

Many TVs use LCD (Liquid Crystal Display) panels that are lit by LED backlights. There are two popular types of LCD panels: In-Plane Switching (IPS) and Vertical Alignment (VA), and there are two main differences between each type. A VA panel usually has a high contrast ratio and narrow viewing angles. However, an IPS panel has low contrast and wide viewing angles. These are the main differences between each, and for the most part, panel type doesn"t affect other aspects of picture quality, like peak brightness, color gamut, or color accuracy.

For the purposes of this article, we"re going to compare two LED-backlit LCD TVs: the Sony X800H, which has an IPS panel, and the Hisense H9G, which has a VA panel. Due to their different panel types, there are three noticeable differences in picture quality: viewing angles, contrast, and black uniformity, so we"re going to look at each one.

Viewing angle refers to the angle at which you can watch the TV without seeing a noticeable drop in picture quality. IPS TVs are the clear winner here, as the image remains accurate when viewing from the side - you can see the differences in the videos above. This is their main advantage over VA panels. Most VA panel TVs have a noticeable loss in image accuracy when viewing from the side. The narrow viewing angle of VA-type TVs is also problematic when the TV is used as a PC monitor from up close since the edges of the display look washed out.

VA panels are far superior to IPS panels when it comes to this, so if you tend to watch movies in the dark, you likely want to get a TV with a VA panel. Most TVs use VA panels due to this main advantage, and high-end models may have a local dimming feature that further enhances black levels. On the other hand, IPS panels normally have low contrast, so blacks look closer to gray, but you may not notice the difference in contrast in bright environments.

Our black uniformity tests determine how well a TV displays a dark scene with a bright image in the center. Ideally, you want to see a completely black screen with the center cross being the only part that"s lit up, and this is important for people watching movies. No LED TV has perfect uniformity, and unlike viewing angles and contrast, the panel type doesn"t completely determine its black uniformity. However, most VA panels that we"ve tested have good black uniformity, while most IPS panels have sub-par black uniformity. This doesn"t mean that every VA panel TV has good uniformity, as this can change between units, and you can also improve uniformity using the local dimming feature.

LCDs function by having liquid crystals in little groups to form the pixels. These crystals react and change position when charged with electricity and, depending on their position, they allow a certain color of light to pass through.

There"s also another type of IPS panel, called Plane-to-Line Switching (PLS), which can be seen with the Sony X800H. This panel type was designed by Samsung and technically performs the same as an IPS panel. When you compare the pixels visually, IPS panels look like chevrons, VA looks like very straight rectangles, and PLS looks like round-edged capsules. You can learn more about pixels here.

The way the pixels are laid out can also affect text clarity. Many IPS panels, like the ones on the Sony X800H or the LG SK9000, use RGB sub-pixel layouts, while many VA panels have a BGR layout, like on the Hisense H9G. The sub-pixel layout doesn"t directly affect picture quality unless you"re using it as a PC monitor. Some applications may expect an RGB layout, so if you have a BGR sub-pixel layout, text may not look clear. You may need to increase the text scaling to read it properly, but this issue isn"t common with an RGB layout. You can learn more about it here.

Unlike LED TVs, OLEDs don"t use a backlight and instead have self-emitting pixels. This allows the pixels to individually turn on and off, resulting in perfect blacks. This means that they also have perfect black uniformity as there"s no blooming around bright objects like on some LED TVs. They also have wide viewing angles, sometimes even wider than some IPS panels, so OLEDs are a good choice for wide seating arrangements.

Samsung released quantum dot TVs in 2015, which they later labeled as QLED in 2017. These TVs include a quantum dot layer between the LED backlights and the LCD panel to achieve a wider color gamut. Other companies like Vizio and TCL also use this quantum dot technology on their TVs. Adding this extra quantum dot layer doesn"t change the characteristics of the panel type; the VA panel on the TCL 6 Series/S635 2020 QLED still has a high contrast ratio and narrow viewing angles. Although most QLED TVs use VA panels, you can easily use an IPS panel as well.

Manufacturers have tried different techniques to improve the viewing angles on VA panels over the years, aiming to produce a perfect LCD panel with both wide viewing angles and high contrast. While they have yet to achieve that goal, a few TVs have hit the market that try to combine the best of both panel types. The first TVs with this viewing angle technology came out in 2018, and only a few high-end models like the Samsung Q90/Q90T QLED and the Sony X950H had this technology in 2020. These TVs are a bit unique, delivering noticeably better viewing angles than their pure VA counterparts, but still worse than true IPS panels. This comes at the expense of a lower contrast ratio, as these TVs have worse native contrast than most VA panels, but they"re still better than IPS panels. Combined with their local dimming features, they still produce deep blacks.

Between IPS and VA panels, neither technology is inherently superior to the other as they both serve different purposes. In general, IPS TVs have wide viewing angles suitable for when you want to watch the big game or your favorite show in a large seating arrangement. They"re also beneficial for use as a PC monitor since the edges remain accurate if you sit up close. However, VA panels are a better choice for watching content in dark rooms, as their improved contrast allows them to display deep blacks. Choosing between the two is a series of trade-offs and qualities, so choosing the best TV for your needs depends on your usage.

Again, IPS is the clear winner here. The vertical viewing angles are very similar to the horizontal ones on both IPS and VA panels. Unfortunately, this is one area where TN panels are usually much, much worse. TN monitors degrade rapidly from below, and colors actually inverse - resulting in a negative image that can be distracting. For this reason, if you decide to buy a TN monitor, look for one with an excellent height adjustment, or consider buying a VESA mounting arm, as you should mount TN monitors at eye level. Even when mounted properly, larger TN displays can appear non-uniform at the edges.

There"s usually not much difference between VA and IPS panels in terms of gray uniformity. It"s rare for monitors to have uniformity issues, and even on monitors that perform worse than average, it"s usually not noticeable with regular content. TN monitors tend to perform a bit worse than usual, though, and the top half of the screen is almost always darker than the rest, but that"s an artifact of the bad vertical viewing angles.

Black uniformity tends to vary significantly, even between individual units of the same model, and there"s no single panel type that performs the best. It"s rare for monitors to have good black uniformity, and almost every monitor we"ve tested has some noticeable cloudiness or backlight bleed. IPS and TN panels can look slightly worse due to their low contrast ratios, as the screen can take on more of a bluish tint when displaying dark scenes. Like with contrast, black uniformity issues usually aren"t very noticeable unless you"re looking at dark content and you"re in a dark room. If you only use your monitor in a bright environment, generally speaking, you don"t need to worry about black uniformity.

Historically, TN panels used to have the worst colors, as many of them were cheaper models that only supported 6-bit colors or used techniques like dithering (FRC) to approximate 8-bit colors. Most displays today, including TN models, are at least 8 bit, and many of them are even able to approximate 10-bit colors through dithering. New technologies, like LG"s Nano IPS and Samsung"s Quantum Dot, add an extra layer to the LCD stack and have significantly improved the color gamut of modern IPS and VA displays, leaving TN a bit behind. Between them, NANO IPS is slightly better, as it tends to offer better coverage of the Adobe RGB color space. Although the difference is minor, IPS panels still have a slight edge over VA and TN displays.

Although TN panels have caught up a bit in the SDR color space, they"re far behind when it comes to HDR, so if you"re looking for a good HDR color gamut, avoid TN panels. Between VA and IPS panels, the difference isn"t as significant; however, IPS panels still have a slight edge. The best VA panels top out at around 90% coverage of the DCI P3 color space used by most current HDR content. IPS panels go as high as 98% coverage of DCI P3, rivaling even some of the best TVs on the market. Due to the very high coverage of DCI P3 on both VA and IPS, the difference isn"t that noticeable, though, as most content won"t use the entire color space anyway.

Although not necessarily as noticeable to everyone as the differences in picture quality, there can also be a difference in motion handling between IPS, VA, and TN displays. TN panels historically offered the best gaming performance, as they had the highest refresh rates and extremely fast response times. Manufacturers have found ways to drastically improve the motion handling of VA and IPS panels, though, and the difference isn"t as pronounced.

LCD panel technology has changed drastically over the last few years, and the historical expectations for response time performance don"t necessarily hold anymore. For years, TN monitors had the fastest response times by far, but that"s started to change. New high refresh-rate IPS monitors can be just as fast.

VA panels are a bit of a strange situation. They typically have slightly slower response times overall compared to similar TN or IPS models. It"s especially noticeable in near-black scenes, where they tend to be significantly slower, resulting in dark trails behind fast-moving objects in dark scenes, commonly known as black smear. Some recent VA panels, such as the Samsung Odyssey G7 LC32G75T, get around it by overdriving the pixels. It results in much better dark scene performance but a more noticeable overshoot in brighter areas.

Within each of the three types of LCD we mentioned, other related panel types use the same basic idea but with slight differences. For example, two popular variants of IPS panels include ADS (technically known as ADSDS, or Advanced Super Dimension Switch) and PLS (Plane to Line Switching). It can be hard to tell these panels apart simply based on the subpixel structure, so we"ll usually group them all as IPS, and in the text, we"ll usually refer to them as IPS-like or IPS family. There are slight differences in colors, viewing angles, and contrast, but generally speaking, they"re all very similar.

There"s another display technology that"s growing in popularity: OLED. OLED, or organic light-emitting diode, is very different from the conventional LCD technology we"ve explored above. OLED panels are electro-emissive, which means each pixel emits its own light when it receives an electric signal, eliminating the need for a backlight. Since OLED panels can turn off individual pixels, they have deep, inky blacks with no blooming around bright objects. They also have excellent wide viewing angles, a near-instantaneous response time, and excellent gray uniformity.

OLED panels aren"t perfect, though. There"s a risk of permanent burn-in, especially when there are lots of static elements on screen, like the UI elements of a PC. There aren"t many OLED monitors available, either, but they"ve started to gain popularity as laptop screens and for high-end monitors, but they"re very expensive and hard to find. They"re also not very bright in some cases, especially when large bright areas are visible on screen. The technology is still maturing, and advances in OLED technology, like Samsung"s highly-anticipated QD-OLED technology, are promising.

As you can probably tell by now, no one panel type works best for everyone; it all depends on your exact usage. Although there used to be some significant differences between panel types, as technology has improved, these differences aren"t as noticeable. The two exceptions to this are viewing angles and contrast. If you"re in a dark room, a VA panel that can display deep blacks is probably the best choice. If you"re not in a dark room, you should focus on the other features of the monitor and choose based on the features that appeal to your exact usage. IPS panels are generally preferred for office use, and TN typically offers the best gaming experience, but recent advancements in VA and IPS technology are starting to change those generalizations. For the most part, the differences between each panel type are so minor now that it doesn"t need to be directly factored into your buying decision.

For people that aren’t the most tech-savvy, it would seem that LCD monitors are all the same. But in reality, the opposite is true. There are four major types of LCD monitor panels, all with unique benefits and drawbacks depending on your needs. So, when shopping for an LCD screen, it’s important to consider how you’ll use it, and which type of computer monitor is best suited for that goal. To learn more about LCD, LED, QLED, and other monitor technology types, check out our guide on the types of monitors.

Technically, there are 11 different types of LCD panels, but they’re usually divided into three main categories — In-Plane Switching (IPS), Twisted Nematic (TN), and Vertical Alignment (VA). IPS is considered the top choice while VA is often associated with burn-in, a condition where pixels lose brightness over time and leave image silhouettes on the screen.

IPS panels tend to offer the best color accuracy, image quality, and viewing angles. As a result, these types are the best monitors for designers who demand better image quality to complete their graphic design work. In particular, IPS panels can provide fidelity at viewing angles as wide as 178 degrees.

However, these panels tend to be more expensive because of their enhanced image quality. Likewise, they don’t score as well for refresh rates, which makes them suboptimal for gamers.

IPS panels can be further divided into seven additional versions. While they’re all somewhat similar, how the pixels are structured is different. These include:S-IPS

Super PLS, or Plane to Line Switching, is another twist on IPS panels but is proprietary to Samsung. Their patented technology promises to offer wider viewing angles and 10% more brightness than standard IPS displays.

AHVA — not to be confused with VA panels — was developed by AOU and stands for Advanced Hyper-Viewing Angle. However, it still relies on IPS technology.

And Nano IPS was created by LG Electronics and promises to create a wider color range because of its use of nanoparticles instead of traditional pixels. Additionally, Nano IPS panels tend to have faster refresh rates.

Touchscreen monitors can be any panel variation, it depends on which one you need. However, if you can’t afford one, as they are expensive, then you’ll need to learn how to convert a monitor to touchscreen.

If you’re a budget shopper looking for an LCD screen, TN panels are going to be the most widely available option. While they’re wallet-friendly, this option has fantastic response times. Some TN-based LCDs can offer response times as low as one millisecond, which makes them ideal for gaming. However, TN panels aren’t as competitive when it comes to color accuracy. These panels are only six-bit instead of eight-bit like IPS panels and therefore can’t display all 16.7 million colors found in 24-bit true-color displays.

VA panels are a median choice for people who have a little bit more to spend but aren’t ready to invest in IPS panel technology. While they provide truer color than a TN panel and wider viewing angles, their response time isn’t as competitive. Additionally, VA viewing angles aren’t as wide as an IPS panel.

Although VA panels have higher contrast ratios for better black levels, they struggle with color shifting. This means that depending on your viewing angle, the brightness can vary. And especially for watching television, this can create a lack of detail in darker scenes. However, because of its affordability, this panel is incredibly popular with manufacturers and is often used in computer monitors and televisions. If you need something with closer to 100% of the sRGB color gamut, you’ll want a different option.

This is going to depend on how you plan on using your LCD monitor, along with your budget. Remember that the lowest price isn’t always the best, especially when considering computer monitor lifespan. You want a monitor that will last you a while. And, also consider the different monitor sizes as well. But as a general rule, the three main panel categories are most compatible in the following ways.

IPS panels are ideal for professionals who need true color accuracy for their work. Gamers who are more concerned with image quality will also do well with this pick. Likewise, serious tech aficionados with exacting standards regarding color accuracy, want to avoid color shifting and maximize viewing angles will like IPS panels. Remember that IPS panels include a wide array of subcategories, many of which are proprietary to select electronics brands.

Budget-conscious shoppers that want a decent LCD monitor that won’t break the bank can’t go wrong with a TN panel LCD. Additionally, gamers who want faster response times will also like these panels. And, anyone who isn’t obsessed with technical specs and simply wants an affordable monitor for general use will like these LCDs.

There’s a variety of display panel out there and even more on the way. But looking at all the different types of panels can be baffling. They come in various acronyms, and many of those acronyms are confusingly similar. How do LCD, LED and OLED compare? What about the different types of LCD panels? And how do these different technologies impact your viewing experience for things like gaming? To help, we’ve created this guide so you can gain a firm understanding of today’s display panel technology and which features really matter.

The first type of panels we’ll cover are LCD (liquid crystal display) panels. The main thing to understand about LCD panels is that they all use a white backlight (or sidelight, etc.). They work by shining a bright white light into your eyes, while the rest of the panel is for changing this backlight into individual pixels.

LED stands for light-emitting diode. You’ll often see LCD panels that are LED, but that doesn’t necessarily mean much when choosing an LCD. LED is just a different type of backlight compared to the old cold cathode backlights. While you could congratulate yourself on not using mercury, which is found in cathodes, at this point all LCDs use LED backlights anyway.

The second thing to understand is that LCDs take advantage of a phenomena known as polarization. Polarization is the direction in which the light wave is oscillating, or swinging back and forth at the same speed. Light comes out of the backlight unpolarized. It then passes through one polarizer, which makes all the light oscillate the same way.

Now you have an on and off (and between) switch for light. To produce color all that’s needed is three color filters, red, green and blue, that block all light other than that color from coming through. The difference between different types of LCD panels is mostly in how this in-between liquid crystal part works.

This design allows for fast response times (the time between the panel getting the frame it’s supposed to display and actually displaying it). It also allows for fast refresh rates. Consequently, TN panels are the only 240 hertz (Hz) gaming monitors available right now.

TN panels are cheap but suffer from poor viewing angles due to the “twist” only being aligned in one direction for viewing the panel straight on. They can also have poor color and contrast due to this twist mechanism not being the most precise or accurate.

VA stands for vertical alignment, again referring to the crystal alignment. These came about in the 1990s. Instead of using liquid crystals to twist a light’s polarization, a VA panel’s liquid crystals are aligned either perpendicular (vertical to) or parallel (horizontal to) the two polarizers. In the off state, the crystals are perpendicular to the two opposing polarizers. In the on state, the crystals begin to align horizontally, changing the polarization to match the second polarizer and allowing the light to go through the crystals.

This structure produces deeper blacks and better colors than TN panels. And multiple crystal alignments (shifted a bit off axis from each other) can allow for better viewing angles compared to TN panels.

However, VA panels come with a tradeoff, as they are often more expensive than TN panels and tend to have lower refresh rates and slower response times than TN panels. Consequently, you won’t see quite as many VA panel gaming monitors.

IPS stands for in-plane switching. These panels debuted after TN panels in the mid-1990s. The crystals are always horizontal to the two polarizers and twist 90° horizontally to go from off to on. Part of this design requires the two electrodes (which apply current to the liquid crystal to change its state) to be on the same glass substrate, instead of aligned with each other on the sandwiching glass substrates above and below the crystal (as in other types of LCDs). This, in turn, blocks a bit more light than both TN and VA panels.

IPS panels have the best viewing angles and colors of any LCD monitor type, thanks to its crystal alignment always lining up with the viewer. And while they don’t offer as fast a response time or refresh rate as TN panels, clever engineering has still gotten them to 144hz, and with nice viewing angles you’re not necessarily going wrong with an IPS gaming panel.

How do LCD panels go about reaching HDR brightness when incorrect polarization and color filters block so much light?The answer is quantum dots. These clever little things are molecules that absorb light and then re-emit that light in the color you engineered them to.

Today’s quantum dot layers usually go between a blue backlight and the polarization step, and are often used to produce red and green that more closely matches the color filters, so more light passes through them. This allows more of the backlight to come through instead of being blocked by the color filters, it can also reduce crosstalk, or colors slipping through the wrong subpixel, ensuring better colors of LCDs.

Other uses of quantum dots are being tried, however. One promising one is using QD molecules to replace the color filters entirely, allowing even more light through. Because LCD backlights produce more light than OLED panels (more on those below), this would allow LCDs to become the brightest displays around.

Motion blur/ghosting can be a result of how long an image takes to switch from one to another and how long an image is displayed on screen (persistence). But both of these phenomena differ greatly between individual LCD panels regardless of underlying LCD tech. And both are often better controlled by higher refresh rates, rather than clever panel engineering, at least for LCD displays.

Choosing an LCD panel based on underlying LCD tech should be more about cost vs desired contrast, viewing angles and color reproduction than expected blur, or other gaming attributes. Maximum refresh rate and response time should be listed in any respectable panel’s specs. Other gaming tech, such as strobe, which flashes the backlight on and off quickly to reduce persistence, may not be listed at all and is not part of the underlying type of LCD used. For that kind of info you’ll have to check the detailed reviews here on our site.

OLED, or organic light emitting diode, panels, are different from LCDs. There are no polarization tricks here. Instead, each pixel (or subpixel of red, green, or blue) lights itself up as a voltage is applied to a giant complex molecule called, yep, an organic light emitting diode. The color emitted is dependent on the molecule in question, and brightness is dependent on the voltage applied. OLEDs can reach HDR brightness because their molecules put out the right colors to begin with without being blocked.

Due to its approach to color and brightness, OLEDs have great contrast ratios. There’s no need to block a backlight, so there’s no worries about light bleeding through. Blacks are very black, and colors look great. OLEDs can also strobe, or flash off and on quickly to lower persistence. They can also use a trick called rolling scan.This turns blocks of the screen on and off one at a time, from top to bottom in a roll. This is all done as the image is sent to the screen, which cuts down on persistence blur a lot. This is why every major VR headset that can afford it uses OLED panels today.

Unfortunately, that’s where the advantages of OLED end. Refresh rates of OLED panels have never surpassed about 90Hz. And they’re quite expensive. A large part of that $1,000 iPhone X price is due to its OLED display. The current molecules used in OLEDs also degrade relatively quickly over time, especially those used for the color blue(opens in new tab), making the screen less and less bright.

OLEDs were also supposed to use less power than LCDs, but newer, giant OLED molecules that take less voltage to turn on have yet to appear. And while molecules covering the colors of the P3 HDR gamut are out today, those covering the larger BT.2020 gamut have yet to be found commercially. So OLEDs, while once promising and seemingly the future, have yet to live up to that promise.

A relevant question: If our fastest gaming displays are 240Hz TN panels now, just how fast do we need to go anyway? Well, a 2015 study places maximum human perception at 500Hz. So from that perspective, we’re halfway there. But that’s halfway there with today’s HDR, and not in lightfield 3D, or other possible advancements. And mobile devices could always use displays that take up less power.

In other words, in order to get fancy 3D effects, or much higher brightness, or any other desirable features, a different, new type of panel may be required. MicroLED tech is one such technology; think of it as OLED without the organic part and with the potential to improve contrast, response times and energy usage over standard LED panels. If you want to know more you can go here, but the real takeaway is that MicroLEDs work almost exactly like OLEDs.

Because OLED TVs are newer and generally more expensive, the average buyer is looking at LED/LCD TVs right now. And although there are several features and specifications to consider while shopping—the brand name, HDR compatibility, and refresh rate, just to name a few—there’s one important hardware spec that isn’t widely advertised: LCD panel type.

LED/LCD TVs are so called because of the two things that make up their displays: an LED (Light Emitting Diode) backlight and an LCD (Liquid Crystal Display) panel for that backlight to shine through. LED backlights vary between a variety of implementations, but modern LCDs generally come in one of two panel technologies: IPS (In-Plane Switching) and VA (Vertical Alignment).

Unlike other hardware specifications (which are usually listed on the side of a TV box or on the manufacturer’s website), information about a TV’s LCD panel type is a bit more inside baseball. But panel type has a far greater impact on a TV’s performance than you might expect—it affects contrast, color, and viewing angle as well.

Individual pixels in an LCD display are made up of liquid crystals activated by voltage. How the display arranges its crystals is part of what sets IPS panels apart from VA panels.

IPS (In-Plane Switching) panels are a common display type for both the best computer monitors and TVs. Without getting too far down the rabbit hole, let’s talk a little about how IPS panels distinguish themselves from other types.

Every non-OLED TV on the market today is an LCD TV powered by LED lighting. Individual pixels in an LCD display are made up of liquid crystals activated by voltage—this is what produces color. An IPS panel aligns its crystals horizontally, parallel to the glass substrate.

IPS technology was developed in part to improve the color and wide viewing angle performance of a display. There"s also a range of variations under the IPS umbrella, including ADS, S-IPS, H-IPS, e-IPS, P-IPS, and PLS (Plane-to-Line Switching). But, while they all differ marginally from one another in operation, their core functionality (as compared to VA panels) is the same.

VA (Vertical Alignment) panels represent another common display type, used for both computer monitors and TVs, but especially for the latter where they greatly outnumber their IPS counterparts. Most LED/LCD TVs you"ll find on the market use a VA panel. While IPS panels align their liquid crystals horizontally, VA panels align them—you guessed it—vertically. They run perpendicular to the glass substrate rather than parallel to it. When met with voltage, the crystals tilt, letting light through and producing color.

This positioning changes how the liquid crystals behave. Without any voltage, the liquid crystals in a VA panel do not tilt, which is a better outcome if your goal is to block light and create image depth. Like with IPS, VA panels also come in a few varieties: PVA, S-PVA, and MVA, though again, their core functionality (as compared to IPS panels) is the same.

TN (Twisted Nematic) is an older LCD display type. They"re still relatively common display types for computer monitors—thanks to their lightning fast response times and excellent handling of motion blur. TN panels aren"t typically used in TV production anymore, though.

The cornerstone of picture quality, contrast ratio refers to the range between a display’s darkest black levels and brightest highlights. Because VA-style panels excel at producing deep, dark black levels, this is arguably their biggest strength. VA panels almost always feature deeper black levels than their IPS counterparts, and this goes a long way in creating a detail-rich picture. An IPS panel can mitigate this by serving up an exceptionally bright image to offset relatively shallow black levels.

A TV’s total viewing angle describes how much a viewer can move away from an ideal, head-on viewing position before the contrast and color of the picture begins to deteriorate. Due to the positioning of their liquid crystals, IPS panels excel in this department; they typically offer significantly more viewing flexibility than TVs with VA-style panels. In other words, IPS panels are more reliable for group viewings (or any situation where a viewer might need to sit at an off-angle).

While impressive color production is possible on both display types, IPS panels tend to offer wider colors, given the nature of their hardware. While a wider range of colors tends to spell better color accuracy, the advent of additional TV technologies like quantum-dot color have evened the playing field considerably. In other words, you’re far more likely to notice the benefits of an IPS TV’s wider viewing angle than you are to notice its tendency for wider color.

Here’s the final takeaway: IPS panels are significantly better than VA panels when it comes to viewing angle and somewhat better than VA panels when it comes to color. VA panels, however, almost always offer deeper black levels and better overall contrast. And because they block light better, TVs and monitors using VA panels tend to have better backlight uniformity regardless of LED backlight type.

Unfortunately, not only is it rare to find a TV’s panel type listed on a manufacturer’s website, but it’s increasingly rare for a brand to reveal a TV’s panel type at all—even when we contact brands directly for information. The reason for this caginess has everything to do with marketing; it’s better to keep shoppers focused on the bells, whistles, and impressive performance specs of a TV rather than its potential shortcomings.

To add to the confusion, it’s common for different sizes of the same TV series to mix and match display types; you might find that the 55-inch version of a TV features a VA-style display while the 75-inch model uses IPS.

Fortunately, it’s relatively easy to determine panel type if you have the proper equipment and you know what to look for. Certain test results and viewing characteristics act as tell-tale signs. This is why my colleagues and I make a point of discussing panel type in just about every TV review we publish, and why you should make a point of reading reviews before making a purchase.

Panel type is not the end-all-be-all for LED/LCD TVs. Many other factors, most of them related to the style and intensity of the LED backlight, can have a major impact on factors like contrast, viewing angle, and color intensity. Ultimately, you need to see a TV in person (and ideally in the space it’s going to live in) to get the best idea of how well it creates an image. But by knowing the core differences of IPS vs VA LCD panels, you can at least make some good guesses before you buy.

Unlike the best gaming monitors, IPS and VA TV panels are on an even playing field. TVs with both technologies are capable of high refresh rates of 120Hz, or occasionally 240Hz (although it usually comes at a premium).

If you’re buying a large screen and intend to host movie nights with friends and family, a TV with an IPS-style panel is far more accommodating thanks to its superior viewing angle. Just be aware that certain content—particularly dark content—won’t pop as much on account of the panel’s shallower black levels.

On the other hand, if you want the best possible picture overall, we recommend investing in a TV with a VA-style panel. They’re not always ideal candidates for group viewings, but the vast majority of the best non-OLED TVs you can buy feature this display type.

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ViewSonic VX2722-4K-OLED was unveiled earlier this year but it is now that it hits the stores in China. This monitor features a 27-inch 4K OLED display by JOLED - EPM269Q00V. The panel delivers native 10-bit color bit depth, 250 nits of typical and 540 nits of peak brightness, 109% Adobe RGB coverage, and a native 60Hz refresh rate. The model is VESA DisplayHDR 400 True Black certified. Being an OLED unit, it offers...

ViewSonic VX3480-2K-PRO has been launched in China priced at around CNY 2000, which equals USD 286 roughly. This gaming monitor has a 34-inch VA display with native 8-bit color support, 100% sRGB coverage, ultra-wide QHD resolution - 3440 x 1440 px, and 300 nits of typical brightness. The model is HDR10 certified. It delivers a minimal GTG response time of 3.34 ms and 1 ms MPRT. Most probably the display panel is...

Panel type names are based on the molecule arrangement on a liquid crystal display - LCD monitor - and the changes that occur upon voltage application. LCD monitors - see also LED vs LCD review - adjust the molecule positioning to function, though the way the changes occur immensely impacts your response time and image quality.

While it is the oldest panel technology, a TN panel still has some advantages over the newer VA and IPS panel technologies (see QLED and IPS). For one, they are the cheapest and suitable if you want budget-friendly options . If the extent of color reproduction or better viewing angles is not essential, a TN screen might suit you.

Moreover, TN panels have the least input lag of about one millisecond. A TN computer can operate at fast refresh rates reaching 240 Hz (see 1440p - 240Hz monitors review). For this reason, they are ideal for competitive players seeking gaming monitors (check out the best monitors for Xbox One X and Xbox Series X) that enable them to take advantage of each second. The Benefits of a good monitor for gaming are shown also in our review of monitors for League of Legends.

TN screens also have poor color reproduction. Most TN displays cannot function at 24-bit true color, so they depend on interpolation for accurate shade simulation. This performance can lead to color banding and lower contrast ratios than VA and IPS panel technologies.

TN panels also have a relatively lower color gamut. Only high-end TN monitors display wide color ranges. Many lack a wide-gamut and therefore are unideal for color grading, web design, photo and video editing, or other usages demanding color accuracy.

With their much wider viewing angles compared to TN screens, IPS panels allow you to sit at extreme angles while getting accurate color displays. Those characteristics are also the reason why IPS displays are good for touchscreens in tablets and portable monitors suh as this ZenScreen Touch monitor from Asus or this from Elecrow, an open hardware facilitation company based in China. Unlike a TN screen, you"ll hardly notice a color shift when looking at the screen from an unideal perspective.

IPS panels also have excellent performance in black reproduction, vital in eliminating the washed-out displays typical on TN panels. Regardless, IPS monitors don"t have as high contrast ratios as VA panels.

While TN panels dominate in terms of the refresh rate, IPS panels are now available that support refresh rates even over 240 Hz. For instance, the ASUS TUF VG259QM 24.5-Inch has a 280 Hz refresh rate and features an IPS monitor (see also this 23.8-inch monitor from HP).

TN displays previously had lower lagging than any other panel type, but IPS displays are now at per. LG launched their Nano IPS UltraGear screens boasting of the fastest response times on IPS at one millisecond. Moreover, Samsung"s quantum dot technologies, which will be covered in another post, are more energy-efficient and offer enhanced color accuracy over IPS, as well.

Despite measuring up, you"ll still spend more to get an IPS screen with a one millisecond response time than a similar-rated TN monitor. If you want to benefit from IPS technology at a budget cost, expect an LCD panel at approximately four milliseconds. Dell S2318HN here has gone a step further though, combining IPS and LED - see also "What is OLED?" - technology for some great results.

Another notable demerit dominant in IPS panels is the IPS glow. If this phenomenon occurs, your screen"s backlight shines and blurs your view when sitting at extreme viewing angles. While not the biggest issue, it is something to consider if you like sitting on the side. On the other hand, these types of monitors are thin and lightweight (see "Auzai"s portable monitor", or this Desklab monitor), as well as energy-efficient. Speaking of portability, ASUS mb168b monitor and AOC e1659fwu are also easy to carry and offer good quality at an affordable price.

VA panels form a middle ground between IPS and TN monitors. They have the highest contrast ratios, making them a go-to option for TV manufacturers. While an IPS screen can have 1000:1, comparable VA alternatives may reach up to 3000:1 or 6000:1 contrast ratios.

VA panels feature slower response times than TN and IPS monitors at their best performance. While some VA monitors refresh at up to 240 Hz, they tend to have latency that can cause motion blur and ghosting.

Compared to TN panels, VA screens provide better color reproduction, often supporting full sRGB spectrum even on budget options (see the best monitors under $200 review).

Because of their attributes, VA panels are suitable for general use. However, these panels tend to perform lower in most specs apart from the contrast ratio. VA monitors are pretty excellent in single-player action, flight simulations, or casual gaming.

Media professionals prefer IPS panels to VA panels, given their wider color gamut, though professionals like music producers require different features in their monitors.

Contrary to what you may think, not all LCD TVs are built around the same core panel technology. They can actually have at their hearts one of two really quite different technologies: VA or IPS.

Each, as we’ll see, has its own distinct advantages and disadvantages – so much so that we personally think the type of panel a particular TV uses should be presented right at the top of its specifications list, rather than typically left off altogether. Especially as some brands have been known to actually mix and match VA and IPS panels at different screen sizes within the same TV series.

The VA initialism stands for Vertical Alignment. This name is derived from the way VA panels apply voltage to vertically aligned liquid crystals that have been mounted perpendicularly to the panel’s glass substrate, making them tilt as required to let the necessary amount of light through for each image frame.

The main advantage of VA panels is contrast. Their perpendicular crystal alignment provides greater control over the light passing through each pixel, meaning dark scenes and dark areas look less grey / enjoy better black levels.

The extent to which this strength is exploited can vary greatly between different manufacturers, and depends on any number of secondary factors. The type and position of LED lighting a particular VA screen might be using can have an impact, for instance. There are multiple variations on the VA theme available from different manufacturers, too. As a basic principle, though, black levels and contrast are consistently and often considerably better on LCD TVs that use VA panels.

Because of their ability to control light better, high-end VA panels generally deliver more brightness in real world conditions than IPS ones do. This further enhances their contrast capabilities, and arguably makes them more consistently able to do fuller justice to the wider light range associated with high dynamic range technology.

Being able to deliver dark scenes with relatively little overlying low-contrast greyness additionally means that VA panels tend to achieve more consistent colour vibrancy and toning.

VA panels for use in LCD TVs come from a number of panel manufacturers, including Samsung Display (which makes a so-called SVA variant) and AU Optronics (which makes an AMVA variant). TV brands are able to buy in panels from these and other VA panel manufacturers as they see fit.

Samsung Electronics is the most consistent user of VA panels in its LCD TVs. In fact, until recently pretty much every Samsung TV at every price level used a VA panel. For the past couple of years, though, IPS panels have unexpectedly cropped up in one or two parts of Samsung’s TV range, including 2021’s high-end QN85 series.

Sony predominantly uses VA panels on its most premium TVs, but it also habitually mixes IPS and VA panels across its wider mid-range and entry level LCD ranges. The same goes for most of the other big brands, too, including Panasonic and Philips.

IPS stands for In-Plane Switching. Like VA panels, IPS panels work by manipulating voltage to adjust how liquid crystals are aligned. Unlike VA, though, IPS panels orient their crystals in parallel with (rather than perpendicular too) the glass substrates present in every LCD panel, and rotate their crystals around to let the desired amount of light through rather than tilting them.

By far the biggest and most talked about advantage of IPS technology is its support for wider viewing angles. In fact, one way of identifying IPS panels has traditionally been to look for quoted viewing angles of 178 degrees.

When we talk about wide viewing angle support in relation to LCD TVs, we’re talking about how much of an angle from directly opposite the screen you can go before the picture starts to lose contrast, colour saturation and, sometimes, brightness.

With VA panels the angle you can watch them before the picture starts to deteriorate sharply can be really quite limited – as little as 20 degrees off axis. While we’d say the 178-degree claims for regular IPS panels are rather exaggerated, you can typically sit at a significantly wider angle than you can with VA and still enjoy a watchable picture.

The VA/IPS viewing angle situation is muddied a little by the introduction into a few high-end VA TVs of wide angle technologies based around filters or sub pixel manipulation. These technologies can be associated with other problems, though, such as reduced resolution, and can still struggle to suppress backlight blooming around stand-out bright objects with LCD TVs that use local dimming backlight systems.

Traditionally IPS panels have been associated with – on high-end screens, at least – wider colour gamuts than VA panels can readily manage. They retain this colour gamut better, too, when viewing the screen from an angle. This is why many professional designers, for instance, have tended to prefer IPS technology to VA. There can be some pretty extreme variance in the range of colour supported across different IPS price points, though, and improvements in premium VA solutions – especially the widespread use of Quantum Dot technologies – have largely evened things up, at least at the premium end of the VA market. In fact, with dark scenes, at least, IPS’s issues with black levels and ‘grey wash’ effect can give good VA panels a colour advantage.

As with VA, there are different variations on the basic IPS theme made by different panel manufacturers. LG Display is by far the biggest manufacturer of IPS LCD panels for TVs, but AU Optronics also makes them, as well as, more surprisingly, Samsung – though some of the non-LG Display IPS products seem to be more focused on PC monitors than TVs.

Given how dominant LG Display is in manufacturing IPS LCD panels, it’s not surprising to find that pretty much every LCD TV LG Electronics makes features an IPS panel at its heart. Other TV brands that use IPS panels on at least a few of their TVs each year include Panasonic, Philips, Sony and Hisense. In fact, the only big brand that has tended to shun IPS is Samsung (perhaps because of arch rival LG Display’s dominance of the IPS market).

If you’re able to actually get your hands on an LCD TV, try knocking gently on its screen. If it’s an IPS panel it will feel solid and the picture will only be slightly affected – or completely unaffected – by the impact of your knocks. If it’s a VA panel, the picture will distort quite noticeably around points of impact.

It’s tempting to assume that any TVs with obviously low contrast are IPS while any screen with a narrow viewing angle is VA. As well as depending on having a wide experience of lots of panels, though, there’s just too much variation in the high and low-end fringes of each technology for this approach to be reliable.

Arguably your best bet is to check out a TV model you’re interested in on an industry website called Displayspecifications.com(opens in new tab), which includes usually reliable information on the core panel of pretty much every TV released.

Our long experience of testing VA and IPS TVs, though, has led us to conclude that in general, the sort of person most likely to be turning to us for buying advice will be happier with an LCD TV based on VA technology.

Even after the introduction of newer display technologies, LCDs still remain relevant even today.LCD displays are used for multiple purposes (TV, Monitor, Mobile Phones, Laptops, Automobiles, etc.) and one single configuration cannot satisfy all the purposes. So, LCD displays come with two different panels – VA (Vertical Alignment) and IPS (In-Plane Switching) to satisfy the different viewing needs of consumers.

A VA panel offers a superior contrast ratio but a narrow viewing angle. Contrarily, an IPS panel offers a wide viewing angle but a low contrast ratio.

As mentioned earlier, displays with VA Panels provide a great contrast ratio. You can find VA panels that typically come with contrast ratios of 3000:1 or 6000:1. A comparable IPS panel will only have a contrast ratio of 1000:1.

VA panels have narrow viewing angles. You will only be able to have an immersive experience when you sit straight opposite the display. The wider angles will not provide you the same experience.

In this, the liquid crystals are arranged parallel to the glass substrate instead of the perpendicular alignment. Furthermore, the structure of crystals and the placement of electrodes differ from the one used in VA panels. The electrodes occupy more space that results in lower contrast and brightness of the screen.

With the IPS panels, you can view the TV / monitor from a wide-angle and still get an impressive picture quality. Unlike VA panels, you will notice very little difference in color reproduction when you sit at a wide-angle from the display.

But when it comes to black uniformity, the IPS panels are sub-par. These panels do a poor job in displaying a bright image in the center of a completely black screen.

One more major drawback with the IPS panels is that they exhibit a distinct phenomenon called ‘IPS Glow’. You will notice some light patches on the corners of the screen. This happens when excessive light is passed through the screen.

Initially, IPS panels are mainly used in TVs due to their wide viewing angles, as we can watch TV in our living room from anywhere. But due to their better quality, color accuracy and response time, LCD panels gradually occupied the high-end computer monitor and laptop screens

IPS:These panels have the highest color range. You will be able to enjoy a realistic gaming experience. Besides, they have better viewing angles. So, you won’t notice any drop in picture quality even when you are not sitting in front of your TV / monitor.

VA:Even though the color range is not as great as the IPS panel, it does a pretty good job in showing the color variations. But the viewing angle is narrow. So, you have to sit straight opposite the TV / monitor.

VA panel compensates for its decent color range with an impressive contrast ratio. You will be able to see great detailing in the difference between light and dark colors.

IPS:IPS panels have one of the highest refresh rates. While you easily find an IPS panel with a refresh rate of 144Hz, some of the latest ones come with a refresh rate of 360Hz. If you are a serious online-gamer, digital artist, or video editor, then you have to go with the highest refresh rate within your budget.

VA:VA panels have lower refresh rates than IPS panels. Most VA panels come with a refresh rate of 120Hz. If you want to have a higher refresh rate, then you have to be willing to spend extra. VA panels have a maximum refresh rate of 240Hz.

IPS:IPS panels generally come with a response time of 4 milliseconds. This would suffice for watching TV or playing most games. But, if you are playing racing games or first-person shooting games, you need to have a response time of less than 2 milliseconds.

VA:VA panels generally have a slower response time than IPS panels with 5 milliseconds. So, there is a higher chance for you to experience motion blur. But, some of the VA panels that come with an expensive price tag have faster response times.

IPS:When it comes to the viewing angle, IPS panels far outweigh the VA panels. They have wider viewing angles. You will experience no drop in picture quality even if you sit and watch the TV from an extreme angle.

VA:The VA panels have a very narrow viewing angle. You have to sit as close to the straight axis of the TV to enjoy the picture quality. If you sit wider, there will be a significant loss in the picture quality.

IPS:IPS panels do a decent job in the contrast ratio segment but they are nowhere close to that of VA panels. An IPS panel offers a contrast ratio of 1000:1. When you watch a black color environment in an IPS panel, the black color will be slightly greyed out.

VA:VA panels offer a superior contrast ratio of 6000:1 that is very impressive. It has the capacity to show dark environments as darker. So, you will enjoy the picture detailing shown by the VA panels.

IPS:IPS panels are not really great at displaying the uniform black color throughout the screen. Due to the low contrast ratio, the black color will appear slightly greyed out.

VA:VA panels have a good black uniformity. But it also depends on the TV model you go with. Not all TV models with a VA panel have good black uniformity. But it is safe to say that in general, VA panels have better black uniformity than an IPS panel.

To put it short, the main difference between the panels lies in the alignment of the liquid crystals. The alignment results in the differences in the performance and picture quality of the panels.

The VA panels are ideal for office/study use, high-end PC games, and online games. If you are looking for a panel for mixed usage, the VA panel should still suffice your needs.

The general consumer typically has very limited knowledge about the different types of LCD panels on the market and they take all of the information, specifications, and features printed on the packaging to heart. The reality is that advertisers tend to take advantage of the fact that most people conduct very minimal research before making big technological purchases—in fact, they depend on this to sell higher quantities of commercial monitors. With that in mind, how exactly do you know if you’re actually getting a good quality product that’ll suit your needs? Reading up on all of the different types of industrial LCD monitors is a good place to start!

LCD stands for liquid-crystal display. Over the years, LCD technology has become ubiquitous with various commercial and industrial screen manufacturing. LCDs are constructed of flat panels that contain liquid crystals with light modulating properties. This means that these liquid crystals use a backlight or reflector to emit light and produce either monochromatic or coloured images. LCDs are used to construct all sorts of displays from cellphones to computer screens to flat-screen TVs. Keep reading to learn everything you need to know about the different types of LCD displays on the market.

Twisted Nematic LCDs are the most commonly manufactured and used types of monitors across a wide range of industries. They’re most commonly used by gamers because they’re inexpensive and boast faster response times than most of the other display types on this list. The only real downside to these monitors is that they possess low quality and limited contrast ratios, colour reproduction, and viewing angles. However, they suffice for everyday operations.

In Plane Switching displays are considered to be among the best of the best when it comes to LCD technology as they offer superior viewing angles, excellent image quality, and vibrant colour accuracy and contrast. They’re most commonly used by graphic designers and in other applications that require the highest possible standards for image and colour reproduction.

Vertical Alignment panels fall somewhere in the middle between TN and IPS panel technology. While they have much better viewing angles and higher quality colour reproduction features than TN panels, they also tend to have significantly slower response times. However, even their most positive aspects still don’t come anywhere close to holding a candle to IPS panels, which is why they’re much more affordable and suitable for everyday use.

AFFS LCDs offers far superior performance and a wider range of colour reproduction than even IPS panel technology. The applications involved in this type of LCD display are so advanced that they can minimize colour distortion without compromising on the extremely wide viewing angle. This screen is typically used in highly advanced and professional environments such as in the cockpits of commercial airplanes.

Nauticomp Inc. is the leading designer and manufacturer of high-quality LCD panels and displays. All of our touchscreen displays are made to order and customized according to your specific needs and applications. To learn more about our products, please contact us today.

Our guide to the best monitors for PC gaming explains why those monitors are ideal for playing games at high resolutions and high framerates, but it doesn’t dig deep into the details of monitor technology. That’s what this guide is for: it breaks down what you need to know about modern displays: resolutions, aspect ratios, refresh rates, and the differences between panel types like IPS, VA, and TN.

LCD displays have a native resolution, and running games (or the desktop) below that resolution degrades image quality due to the scaling process of enlarging the image. Using lower resolution modes isn"t really a substitute for picking the right number of pixels in the first place.

1440p has become our recommendation as the best overall option. It"s great for office work, professional work, and gaming. You can still get higher refresh rate 144Hz panels (see below), plus G-Sync or FreeSync, and you can run at 100 percent scaling in Windows. For gaming purposes, however, you"ll want at least a GTX 1070/RTX 2060 or RX Vega 56 (or equivalent) graphics card.

The most common and least expensive LCD panels are based on TN, or Twisted Nematic designs. Since TN screens are made on a vast scale and have been around a long time, they are very affordable. Online retailers stock an abundance of attractive 27-inch 1080p monitors(opens in new tab) with reasonable features starting at just $150. The price is nice, but the pixel density isn’t—and neither are the color quality or viewing angles, TN’s greatest weaknesses.

All TFT LCDs work by passing light, such as an LED, through a pair of polarized screens, a color filter, and liquid crystals that twist when current is applied to them. The more current applied, the more the liquid crystals twist and block light. Precise adjustments allow virtually any color or shade to be reproduced, but TN implementations have some limits.

Each pixel in an LCD display is made of red, green and blue subpixels. Colors are made by mixing varying brightness levels for these pixels, resulting in a perceived solid color to the user. The problem with TN is its widespread adoption of a 6-bit per channel model, instead of the 8-bit per channel used in better displays.

TN compensates for this shortcoming via FRC (Frame Rate Control), a pixel trick that uses alternating colors to produce a perceived third, but it"s a poor substitute for proper 24-bit color reproduction. When combined with the inversion and washout that comes from narrow viewing angles, TN"s elderly status in the LCD display world becomes clear.

IPS, short for In-Plane-Switching, was designed to overcome TN"s shortcomings as a display technology. IPS screens also use liquid crystals, polarized filters, and transmitters, but the arrangement is different, with the crystals aligned for better color visibility and less light distortion. Additionally, IPS panels typically use 8-bit depth per color instead of TN"s 6-bit, resulting in a full 256 shades to draw upon for each color.

The differences are pretty dramatic. While TN displays wash out at shallow angles and never truly "pop" with color no matter how well they are calibrated, IPS panels have rich, bright colors that don"t fade or shift when viewed from the sides. Moreover, pressing a finger on an IPS screen doesn"t cause trailing distortions, making them especially useful for touchscreen applications.

The complexity introduces additional overhead that reduces panel responsiveness. Most IPS displays clock in a few milliseconds slower than TN panels, with the best models managing 5ms grey-to-grey, and the more common 8ms panels can have noticeable blurring in gaming. Most IPS displays use a 60Hz refresh rate, though the best gaming displays now utilize IPS panels with 144Hz refresh rates, and a price to match.

A lot of research has been done with IPS and many variants exist, including Samsung"s popular PLS panels and AU Optronics AHVA (Advanced Hyper-Viewing Angle). The differences amount to subtle manufacturer variations or generational improvements on the technology, which has been around since 1996.

In between the high speed of TN and the color richness of IPS sits a compromise technology, the VA, or Vertically Aligned, panel. VA and its variants (PVA and MVA, but not AHVA) normally take the IPS approach with 8-bit color depth per channel and a crystal design that reproduces rich colors but retains some of the low latency and high refresh speed of TN. The result is a displa