types of lcd panel in stock

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.

Contrast ratio is one of the most important factors when it comes to picture quality. It determines how well a TV displays blacks, so one with a good contrast displays deep blacks when viewed in the dark. However, if your TV has a low contrast ratio, you"ll notice that blacks look gray when viewed in the dark.

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.

However, the one major downside to OLEDs compared to LEDs is their risk of permanent burn-in. This could be problematic if you constantly watch content with static elements, like the news, or if you use it as a PC monitor. We don"t expect it to be an issue for people who watch varied content, but if you"re truly worried about it, LED TVs appear to be immune to burn-in.

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.

In order to choose the best monitor for your needs, it is very important to distinguish what kind of LCD panel interface type is in the monitor you’re looking at. The most common panels used nowadays are;

One of the types of panels that you will find in a computer monitor is a TN Panel. This stands for Twisted Nematic, and this particular type of LCD panel is generally the cheapest. They are the cheapest to manufacture among all LCD technologies, so they are the most commonly used in budget monitors.

If you are looking to game online, you will need a monitor with a higher refresh rate like that offered by a TN panel. Refresh rates are measured in Hertz (Hz), which defines how many times per second your screen can display new images.

The typical response time for a TN panel is less than 5 ms which is much faster than the 6 or 8 ms response time that other LCD displays have, such as vertical alignment or VA.

The biggest downside with these panels is often their viewing angles. On a TN panel, the viewing angles aren"t very good, and depending on how far off-center you are, the picture can begin to lose color and contrast.

TN panels also don"t support as wide a range of resolutions as IPS. This LCD monitor panel type has a poor contrast ratio when compared with other technologies such as IPS and VA. This results in an inability to display deep blacks and bright whites at the same time.

TN panels are manufactured by Samsung, LG, AUO, Chi-Mei, Chunghwa Picture Tubes, Hannstar Display Corporation, Sharp Corporation, CMI, Innolux, J-Tech Digital Imaging Co. Ltd, AU Optronics Corporation, etc.

A TN panel is a type of liquid crystal display (LCD) used in most LCD monitors and laptops. TN panels were the workhorse of the 1990s and early 2000s, but they were eventually replaced by their more-expensive cousins, the in-plane switching (IPS) and vertical alignment (VA) panels.

TN computer panels work by using two polarized filters, vertical and horizontal, to control the light that passes through them. The filters are arranged so that when the electrical current is off, light cannot pass through. When it"s on, it hits the twisted crystals to produce colors. The active layer is twisted to allow the light to pass through it, and this twist is controlled by electrical fields applied to the liquid crystal material.

It is worth noting that A TN panel is made up of millions of pixels, each pixel being red, green, or blue in color. The light from each pixel can be either on or off, so black is created when all the pixels are off and white when all are on. When all three colors are combined, any color can be produced. This arrangement is called RGB (red-green-blue).

A TN panel uses twisted nematic liquid crystals to form images. While not as desirable as other technologies, it does have several benefits worth considering when making a purchasing decision.They are mostly found in budget LCDs, as they are cheaper to manufacture and therefore sell for less.

TN panels have excellent response rates and refresh rates, typically 1 - 2 milliseconds and 50 – 75 Hz, respectively. This makes them ideal for high-end gaming

TN is the oldest and most common type of LCD panel, and it"s also the cheapest to produce. TN panels were the first panels to be introduced to the market, but they"re no longer as popular as they used to be. This is because TN panels have several downsides:The main disadvantage of TN panels is limited viewing angles, which can be extremely limiting in some cases. If you"re sitting straight in front of the monitor, everything is fine, but if you move to the side, then all colors shift and get distorted. That can be extremely annoying for graphic designers or architectswho work with color palettes, photographers who need exact color matching, etc. (see also

TN panels typically have lower contrast ratios than IPS displays do, so they don"t look as rich in color or dark black. So TN panels are usually not suitable for professional applications such as color-critical photo editingand graphic design.

Many gamers prefer TN panels because they provide a very fast response time and higher refresh rates. You can also find some with a refresh rate of 240Hz, which is even better.The Asus VG248QE is a 24-inch LCD display with a 1920 x 1080 resolution and a 1ms response time. It uses a TN panel, so don"t expect much in terms of viewing angle or color reproduction accuracy compared to an IPS display. But if you"re looking for a good 144Hz monitor, choose this one.

The Samsung S27B970D is also known as the professional gaming monitor because it has features that gamers love: it"s got a fast 1ms response time and 144Hz refresh rate. In addition, as far as features go, take a look at gaming monitors with speakers.

ViewSonic VX2458-MHD. It has a TN panel. The refresh rate of this monitor is 72Hz, which is standard. The response time of this monitor is 1ms. It also comes with 4 USB 3.0 ports, which is great if you plan on hooking up multiple devices, which is frequently used when trading. If you have a setup like that, you will also want to look at bezel less monitors, or frameless monitors, for your needs.

Another common type of panel is a VA panel. This stands for Vertical Alignment and is a step above a TN panel in terms of quality. Its name comes from the fact that light emitted from the screen"s backlight (see also LED monitors) is aligned vertically rather than being scattered horizontally and vertically as it is with a TN display.

VA panels provide high-quality images, wide viewing angles along with excellent contrast ratio and high refresh rates. These factors make VA panel monitors preferred for graphic design, photographers, video editors, and others who often work on their PCs.

VA panels are also better when displaying fast-moving images because they offer high refresh rates hence have less motion blur. Additionally, some panels have support for even 120 Hz refresh rates for ultra-smooth movement in games and movies.

Unlike a TN display, a VA display has excellent viewing angles. You can view them from any direction, and you won"t see any distortion in the display. They make them a good choice for home theater systems as it allows users to be seated off-center without affecting the image quality or contrast ratio.

Traditional LCD displays use two polarizing filters and liquid crystals (LCs) to create all the colors and patterns that we see on computer monitors and flat-panel televisions.

What are the Benefits of VA Panels?Image quality of VA technology is considered better than TN technology; text appears crisper, and images appear sharper and richer in contrast and color.

One of the other key benefits of VA technology is its high contrast ratio; VA displays can deliver a true black when displaying dark images or video content

VA displays also offer an ultra-wide viewing angle, which means that you can view them from a wide range of angles without experiencing color distortion.

The big downside of TN panels is their response time. Most TN panels have a response time of 5-8 MS, which is fine for most people. However, if you"re mostly into competitive gaming or fast-paced action games like me that require quick reflexes, then this could be a problem.

We did some research and came up with a list of the best monitors with VA panels, and they are;ViewSonic VX2457-MHD. It is a24-inch monitor with a 1920 x 1080 resolution and covers 100% of the sRGB spectrum. It also has plenty of picture-enhancing features, including adjustable color settings and support for AMD"s FreeSync technology (see also affordable G Sync monitors).

This is the best LCD panel type. IPS stands for In-Plane Switching, and the biggest advantage over the other panels listed above is its wide viewing angles.

These screens are more expensive than TN panels but offer a greater contrast ratio, higher resolutions than their TN counterparts. They also support higher refresh rates, lower response time which makes them ideal for monitors larger than 24 inches.

These panels offer much more consistent colors, which makes them ideal for graphic designers or anyone who does any kind of color-critical work on their monitor.

IPS panels offer wider viewing angles than VA panels do, making them better suited for use in public spaces such as retail stores or airports where you can expect people will be walking by your TV from both sides.

They also have a high refresh rate. Newer models are now available with 120Hz or even 240Hz refresh rates. These are found chiefly on gaming monitors but will likely become more common in other types of monitors in the future.

The contrast ratio of an IPS panel is higher than that of TN panels. The contrast ratio of a display refers to the difference between the darkest black and the brightest white that the display is capable of producing. This can be an important factor in overall display quality, depending on how you use your laptop or desktop monitor.

Some manufacturers that specialize in IPS panel interphases include Samsung, LG, and even Mac Apple. Also, almost all Dell monitors use IPS panels. However, there are plenty of other high-quality manufacturers that also offer IPS panels for you to choose from.

In a liquid crystal display (LCD), light passes through a pair of polarizers. Each polarizer is made of a long chain of molecules, each oriented in a different direction; one vertical, the other horizontal.

When an electric current is applied to the liquid crystals, their long chains align with the directions of the polarizers. If both polarizers are vertical, no light will pass through. But if one polarizer is vertical and the other is horizontal, light can pass through.

In an IPS LCD panel, liquid crystals are aligned so that both polarizers face the same way—horizontal. Light from behind the panel passes through one polarizer and then bounces off onto a second polarizer before reaching your eyes. This design makes IPS LCDs nearly as bright as VA panels and much brighter than TN panels without sacrificing contrast ratio or color accuracy.

If you"re looking for a new monitor, IPS panels may be the right ones for you. Here are some of their most important benefits:It allows for wider viewing angles. This is very useful for monitors used at work that involve customer service, where the monitor may be viewed from many different angles.

The IPS LCD displays are also characterized by their high degree of brightness and contrast, which makes them ideal for outdoor use, among many other features.

The typical lifespan of an IPS panel is around 100,000 hours, which is more than enough for even heavy users to get their money"s worth from their monitor.

They"re thin and lightweight which makes them ideal to serve as portable monitors. A major benefit of IPS monitors is that they"re easy to carry around because they"re so thin; they’re also easy to pack up in a bag when you"re traveling or moving from place to place.

They have great color reproduction. Many people who are serious about a photo or video editing are drawn to IPS panels because they offer superior color reproduction possibilities when compared with TN panels.

The main disadvantage of IPS panels is that they are more expensive than TN panels. The cost of an IPS panel will typically be $10-$20 higher than a comparable TN panel.

Today, the majority of flat-panel monitors use in-plane switching (IPS) technology. Best monitors that have IPS panels include;Samsung U28E590D 28-Inch 4K UHD Monitor. If you love gaming, then this is the product for you; it comes with AMD FreeSync, which proved successful in eliminating screen tearing since being introduced as VSync, as this post explained.

Also, bear in mind that if it is a flat panel display with a 1080p resolution or higher, you can refurbish it and resell it after using it. Older monitors with lower resolutions may not be worth much.

It offers a much higher resolution than conventional LCD and can be used to manufacture large panels. It"s an innovative display technology that has the potential to change the face of consumer electronics.

There are 3 main types of LCDs; VA (Vertical Alignment), TN (Twisted Nematic), and IPS (In-Plane Switching). All these technologies have been used for over 10 years and have their own pros and cons. However, they have reached their upper limits in terms of resolution and other features, and it"s nearly impossible to increase them any further. That"s where Super PLS-Plane to Line Switching comes in.

Super PLS-Plane to Line Switching offers resolutions as high as 8K, has wider viewing angles, and is brighter. The image quality presented by this technology is said to be much better than traditional LCDs, and it could potentially disrupt the current.

The Nano IPS panel technology adds a layer of nano-particles to the backlight in order to transmit the screen"s picture more efficiently and reduce the chances of image retention.

The nano-particles increase the amount of light that is transmitted through each pixel, improving the overall brightness and color accuracy of the display. This means that great image quality can be achieved at lower backlight levels.

Advanced Hyper-Viewing Angle (AHVA) computer display was developed by AU Optronics Corp. It is a type of LCD that can be seen clearly even from the most acute angles. Through the process of strengthening the polarizing plate, it can help minimize the reflection ratio to less than 1%. The viewing angle is about 178 degrees.

AHVA also provides a greater range of colors which makes images appear to pop off the screen. And it gives better performance outdoors, so you get a great view no matter whether it"s sunny or cloudy.

Computer monitors produce a lot of blue light, which isvery bad for your eyes. Why? Because blue light has the highest energy and the shortest wavelength in the visible light spectrum. If you stare at a computer screen for hours each day, you"re exposed to a lot of blue light, and that can be very harmful to your eyes. For programmers, for example, who spend a lot of time under artificial light, to have the best eye care technology is crucial to keep focus on the job.

Most LCDs (liquid crystal display) monitors are now manufactured with an anti-glare coating to reduce the effect of ambient light reflecting off the screen. Anti-glare coatings can reduce reflections by 25 to 70%.

VA panel is better thank IPS. Although IPS panels have a contrast ratio of 700:1 to 1500:1, they are still inferior to VA panels. The majority of VA monitor panels have contrast ratios above 2500:1, and some even reach 5000:1 or 6000:1. Even local dimming is used by more recent monitors to obtain even greater contrast ratios.

Yes, IPS is better than OLED. The main benefit of IPS panels is their increased brightness, particularly when combined with a tiny LED backlight. OLED displays are often limited to brightness levels of roughly 1,000 nits, while mini LED displays can reach peak brightness levels of around 2,000 nits.

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.

Flat-panel displays are thin panels of glass or plastic used for electronically displaying text, images, or video. Liquid crystal displays (LCD), OLED (organic light emitting diode) and microLED displays are not quite the same; since LCD uses a liquid crystal that reacts to an electric current blocking light or allowing it to pass through the panel, whereas OLED/microLED displays consist of electroluminescent organic/inorganic materials that generate light when a current is passed through the material. LCD, OLED and microLED displays are driven using LTPS, IGZO, LTPO, and A-Si TFT transistor technologies as their backplane using ITO to supply current to the transistors and in turn to the liquid crystal or electroluminescent material. Segment and passive OLED and LCD displays do not use a backplane but use indium tin oxide (ITO), a transparent conductive material, to pass current to the electroluminescent material or liquid crystal. In LCDs, there is an even layer of liquid crystal throughout the panel whereas an OLED display has the electroluminescent material only where it is meant to light up. OLEDs, LCDs and microLEDs can be made flexible and transparent, but LCDs require a backlight because they cannot emit light on their own like OLEDs and microLEDs.

Liquid-crystal display (or LCD) is a thin, flat panel used for electronically displaying information such as text, images, and moving pictures. They are usually made of glass but they can also be made out of plastic. Some manufacturers make transparent LCD panels and special sequential color segment LCDs that have higher than usual refresh rates and an RGB backlight. The backlight is synchronized with the display so that the colors will show up as needed. The list of LCD manufacturers:

Organic light emitting diode (or OLED displays) is a thin, flat panel made of glass or plastic used for electronically displaying information such as text, images, and moving pictures. OLED panels can also take the shape of a light panel, where red, green and blue light emitting materials are stacked to create a white light panel. OLED displays can also be made transparent and/or flexible and these transparent panels are available on the market and are widely used in smartphones with under-display optical fingerprint sensors. LCD and OLED displays are available in different shapes, the most prominent of which is a circular display, which is used in smartwatches. The list of OLED display manufacturers:

MicroLED displays is an emerging flat-panel display technology consisting of arrays of microscopic LEDs forming the individual pixel elements. Like OLED, microLED offers infinite contrast ratio, but unlike OLED, microLED is immune to screen burn-in, and consumes less power while having higher light output, as it uses LEDs instead of organic electroluminescent materials, The list of MicroLED display manufacturers:

LCDs are made in a glass substrate. For OLED, the substrate can also be plastic. The size of the substrates are specified in generations, with each generation using a larger substrate. For example, a 4th generation substrate is larger in size than a 3rd generation substrate. A larger substrate allows for more panels to be cut from a single substrate, or for larger panels to be made, akin to increasing wafer sizes in the semiconductor industry.

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Picture quality of a monitor is affected by many factors. These factors include panel type, driver IC and PCB, backlight system, different light filters, etc., but without any doubt, panel type is one of the most important aspects of picture quality on a monitor screen.

In the last few years many consumers blindly put all their trust in IPS panels. They are quick to assume an IPS panel is the best overall and ignore the fact that each panel type has their own pros and cons.

Right now, the mainstream monitor panel types include TN (Twisted Nematic), IPS (In Plane Switching), and VA (Vertical Alignment). Each type of panel carries their own set of unique features and qualities. To assist you in your next purchase decision, this article will compare the three panel types and provide you a better understanding of how these panels differ.

TN panel is the first LCD panel that has been widely used in desktop monitors, and it still holds a large share of the market. It is a very basic LCD panel, with a backlight module on which the position of each pixel dot has three light filters that allow only red, green, or blue light to pass respectively. The mix of three colors at different levels of brightness produces the content on the screen.

Faster response time. It’s max response time of 1ms is simply superior and unachievable by other panel types. As a result, it’s great for enthusiast gaming.

IPS, also known as Super TFT, it was invented by Hitachi in 1995. Its greatest characteristic is both its electrodes, they are on the same plain unlike all other panel types that locate them on two different plains. Because of this feature, its liquid crystal molecules are always parallel to the panel. This reduces the light pass through rate and requires more back lighting.

Great picture quality. IPS panel on monitors was originally intended for professional monitors for content creators who require great color reproduction, color accuracy, and viewing angles.

VA was invented by Fujitsu in 1998 in search of a middle ground between TN and IPS. Once it’s powered on, its liquid molecules are aligned in vertical arrays that allow light to pass through different arrays. At the time it was believed VA would take over the throne from TN immediately, but it never happened, due to VA pane’s higher cost of production and slower response time.

Though TN panel still holds a large share of the monitor market, it is completely unacceptable if you have any expectations in picture quality and viewing angles.

High end IPS monitors are superior if you are a professional content creator or simply want the best picture quality. Mid-tier IPS monitors should be considered only if you don’t game at all.

VA monitors strike a perfect balance in cost and performance. Considering the era of HDR is right around the corner, the deep contrast ratio of VA will continue to shine even more.

Everyday, we look at LCD display, TV, cell phone, monitor. It becomes a necessity in modern society. LCD panel is the most important part of an LCD display. It determines LCD screen"s performance, e.g. brightness, contrast, color and viewing angle. Therefore, picking the right type of LCD panel is critical to your application.

These names reflect the alignment of crystal molecules inside the LCD, and how they change when they are charged electrically. All liquid crystal displays change the alignment of liquid crystal molecules to work, but the manner in which they do so can drastically affect the image quality and response time. Each panel type has its advantages and disadvantages. The easiest way to choose between them is to decide which attributes are most important to your project. It mainly depends on what you use your LCD display for, and your budget.

TN is the most mature technology in LCD panel manufacturing. When there is no voltage difference between the two transparent electrodes, liquid crystal molecules are twisted 90 degrees, in combination of upper and bottom polarizers, allows light to pass through LCD. As voltage applied, crystal molecules are untwisted and aligned to the same direction, blocking light.

In IPS panel, crystal molecules are parallel to the glass substrates at initial stage, LCD is off. When the in-plane electrodes is charged, crystal molecules are rotated, modifying light"s direction. Which lights up the LCD display.

As its name suggests, VA panel"s liquid crystals are aligned vertically without charged. When a voltage is applied, the molecules tilt and modifying light direction.

So in summary, TN panels twist, IPS panels use a parallel alignment and rotate, while VA panels use a perpendicular alignment and tilt. These difference create LCD display with distinctive performance.

IPS LCD is the clear winner in this aspect. It has 178/178 viewing angle ratings. Which means you can look at IPS LCD display from any angle without the image shifting in color and contrast. VA LCD has pretty wide viewing angle, too. But it has contrast shifts at off-center angles. As for TN LCD, viewing angle is its weakest point.

Most TN LCDs have 6-bits colors. Manufacturers use frame rate control (FRC) to enhance its color performance. For IPS and VA panels, you can still find 6-bits entry level LCD. But most of them are 8-bits. And IPS technology can provide natively 10-bits colors.

Color gamut is another part that VA and IPS panels shine at. The best TN LCD can reach sRGB gamut. VA panels typically start with full sRGB coverage, and get to around 90% DCI-P3 coverage. With IPS LCD panel, you could find the best ones full DCI-P3 and Adobe RGB coverage. That is why you see most professional grade LCD displays use IPS panel.

There is no inherent differences among the three panel technologies, because LCD backlight is the main factor here. However, there is a big gap in terms of contrast ratio. TN LCD panel tends to have the lowest value among the three. IPS LCD screen sits in the middle can reach 1500:1. For VA panel, the best one can exceed 4500:1 easily. VA LCD display provides far darker screen than TN & IPS. That is why they are used in vehicle dashboard.

TN panel does have an advantage when it comes to refresh rate. The panel offers the best refresh rate and response time. This is the reason why most gaming LCD monitors are made of TN panel.

TN LCD provides the best refresh rate and economic solution. If your application requires wide viewing angles and good color presentation, VA panel is probably the choice. While IPS has the best overall visual performance, in general it is more expensive than the other two.

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Picking a monitor may feel more like art than science, but the technology behind the screen isn"t hard to understand. Learning about those technologies is key to navigating the minefield of marketing buzzwords separating you from your next monitor.

For example, numbers like contrast ratio and grey-to-grey response time are important, but they don’t tell the whole story—other specifications like input delay and color bit-depth are just as important. And while it"s sort of possible to find a monitor that can do it at all, the price can be very high. There are displays suited to gaming, design work, and ultra-high resolution detail, but mixing priorities often results in compromise. Fast, colorful, or high-DPI—pick any two, but the third will cost you.

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.

While you might be inclined to go after the highest pixel count you can find or afford, this isn"t always the best strategy for finding an optimal display. Higher resolutions offer greater detail but require faster graphics cards for gaming purposes, and Windows" DPI scaling still isn"t perfect. How you use your PC as well as your hardware will help determine the ideal resolution and size for your next display.

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.

PC Gamer is going back to the basics with a series of guides, how-tos, and deep dives into PC gaming"s core concepts that we"re calling The Complete Guide to PC Gaming. There"s much more to come, and it"s all being made possible by Razer(opens in new tab), which stepped up to support this months-long project. Thanks, Razer!

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.

Beyond 1440p, gaming gets dicey and expensive multi-GPU setups are often required for acceptable performance (though many games don"t even support multi-GPU, so that"s not always a viable solution). 4k displays are where most PCs top out, and while 5k and even 8k displays exist, those resolutions represent the bleeding edge of monitor design and generally aren"t useful for gaming purpose.

Realizing any serious performance aspirations at 3840x2160 requires an ultrafast graphics card (eg, GTX 1080 Ti/RTX 2080 or even 2080 Ti), and possibly two such GPUs. That could mean a cool $1400-$2400 just for the graphics subsystem. But if you want bragging rights and the ultimate rig, there"s nothing equal to a 4K display. 4k HDTVs have also become quite affordable, some of which can make a good alternative to a computer monitor.

If you want something more than the standard 16:9 aspect ratio, there are three primary options. Multi-monitor solutions are the most cost effective choice, where you buy two or three (preferably identical) displays and use them independently. Software developers, content creators, and other professionals can increase productivity by adding displays, and most graphics cards can easily drive three monitors.

Ultrawide 2560x1080 and 3440x1440 displays go after a middle ground, and are particularly popular among movie viewers. Most films are natively recorded at a 21:9 (or similar) "cinemascope" aspect ratio, and viewing these on a 16:9 display means you"ll end up with black bars on the top and bottom. The wider screens also provide a more immersive experience in 3D games, mimicking a full field of vision closely without the bezel interruptions of multi-monitor setups.

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.

While touted as the high end display technology of choice by giants such as Apple, the truth is that IPS screens still have drawbacks. Due to their more complex construction and the additional transmitters and lighting required for each pixel, IPS screens cost more than their TN counterparts. Thankfully, over the past few years, the popularity of no-frills import IPS monitors from Asia has helped drive down prices and force bigger monitor brands to sell more reasonably priced IPS displays.

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 display that"s theoretically almost as colorful as IPS and almost as fast as TN.

VA panels have a few unique qualities, both positive and negative. They have superior contrast to both IPS and TN screens, often reaching a static 5000:1 ratio, and produce better black levels as a result. Advanced VA variants, such as the MVA panel used by Eizo in the Foris FG2421, support 120Hz officially and offer pixel latencies on par or better than IPS.

The flood of innovation in the display market shows no signs of abating, with TVs on one side and smartphones on the other driving new technologies such as curved screens and desktop-grade OLED panels that promise speeds, contrast and color beyond anything seen so far.

Most standard TFT-LCDs support a refresh rate of 60Hz, which means the screen is redrawn 60 times each second. While 60Hz may be sufficient for many desktop applications, higher refresh rates are desirable since they provide a smoother experience moving windows, watching video, and especially when gaming.

A refresh rate of 120Hz or even 144Hz alone isn"t sufficient for blur-free gaming however, and closing that gap has been an area of focus for display makers in recent years. Much work has been done to supplement high refresh rates with additional features meant to reduce motion blur further.

One method popular in gaming monitors is the inclusion of a strobed backlight, which disrupts eye tracking blur by cutting off the backlight for an instant, creating a CRT-like stable image. A strobed 120Hz display is more blur-free than a non-strobed 144Hz panel, but flickering the backlight understandably cuts down on the overall brightness of the image. Users with sensitive eyes can suffer from eyestrain and headaches induced from the flicker as well.

In addition to motion blur, another visual artifact that frustrates gamers is tearing. Tearing occurs on a monitor when a GPU sends a frame to the display before it"s finished displaying the current one. This results in the lower part of the screen displaying one frame and the top part displaying the other, separated by a line across the image. Enabling V-Sync, which forces the graphics card to wait on the monitor for refresh, can reduce this problem, but V-Sync has issues of its own including increased input latency and rigid frame rate requirements.

To get around this, GPU manufacturers have introduced a pair of technologies that dynamically synchronize the monitor and GPU framerate, eliminating tearing without VSync"s lag or heavy overhead. Nvidia calls their implementation G-Sync, and it requires a module built into the monitor as well as a GTX 650 Ti or later graphics card.

Action gamers looking for competition-level, frame-accurate inputs are best served by displays with minimal onscreen menus, little to no post-processing of images, and just a single port or two. This insures the video signal spends as little time bouncing around the monitor"s scaling and processing hardware as possible and gets displayed without delay.

The good news is that higher performance scaler hardware has helped reduce input latencies, and modern displays can offer multiple inputs while still providing excellent responsiveness. Along with FreeSync 2 monitors, Nvidia"s BFGD (Big Format Gaming Displays) aim to be a one size fits all solution.

RF2G8A3MY–Printed circuit board connected by flexible flat cable to LCD panel. Closeup of electronic components - micro chip, inductor or capacitor on green PCB.

RF2D74NJ6–Vector realistic TV led screen isolated on transparent background. Modern stylish lcd panel. Computer monitor display mockup. Blank television graphic

RFK8P262–Realistic TV screen hanging on the wall. Modern stylish TV lcd panel isolated. Large led computer monitor display mockup. Vector illustration

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RF2BGEP3B–Empty tv frame with reflection and transparency screen isolated. Lcd monitor vector illustration. Lcd display screen, tv digital panel plasma

RMW6KMNM–Chinese workers labor at the Xianyang High-tech Industrial Development Zone for CEC¤Xianyang 8.6-generation LCD panel production line project in Xiany

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RMDHJ99T–Flat panel 40" (diagonal) LCD television in room setting with photographers own copyright image inserted onto TV (see Alamy additional info panel)

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RMW6KPKF–Chinese workers labor at the Xianyang High-tech Industrial Development Zone for CEC¤Xianyang 8.6-generation LCD panel production line project in Xiany

RF2D74NP2–Vector realistic light TV led screen isolated on white background. Modern lcd panel. Computer monitor display mockup. Blank television graphic design

RF2F8F25R–The backlight inverter in the LCD TV. it is a device for starting and stable operation of fluorescent lamps of the LCD panel backlight. Isolated on a

RFHRCPND–Interior car lever - button, design, dashboard, cluster instruments, lcd panel, door handle, climatronic function, sport steering wheel, Honda Civic

RF2F7EWC6–Detail of a LED or LCD panel for screen on concerts or different displays. Focus on a centre row of LED lights, others in soft focus. Array of LED RGB

RMW6KMFW–Chinese workers labor at the Xianyang High-tech Industrial Development Zone for CEC¤Xianyang 8.6-generation LCD panel production line project in Xiany

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RFHRCPNC–Interior car lever - button, design, dashboard, cluster instruments, lcd panel, door handle, climatronic function, sport steering wheel, Honda Civic

RF2F7EWCF–Detail of a LED or LCD panel for screen on concerts or different displays. Focus on a centre row of LED lights, others in soft focus. Array of LED RGB

RF2E9B613–Tv Screen Display. Black Monitor Design. Digital Lcd Panel. Wall Led Equipment. Modern Plasma Vector Mockup. Flat Technology High Definition Device. E

RMW6KN9M–Chinese workers labor at the Xianyang High-tech Industrial Development Zone for CEC¤Xianyang 8.6-generation LCD panel production line project in Xiany

First, to be clear, there is no “best” panel type out of these, as all have their respective advantages and disadvantages over the others. The information here pertains to general characteristics, as even panels of the same panel type will have some variance in characteristics (power consumption, backlight bleed, etc.) depending on the luck of the draw. Manufacturer tuning can also impact display output, affording some differentiating leverage to manufacturers sourcing from panel suppliers (which is effectively all of them).

The earliest widely available and used consumer PCs employed CRT (Cathode Ray Tube) monitors. For this reason, CRT monitors are oftentimes remembered in fondness (or contempt) by those who grew up using them.

Nostalgia or riddance aside, there are still some valid reasons to use a CRT monitor. When compared to LCD panels, CRT monitors can have higher contrast ratio, very low response time (which leads to non-blurred pictures even with fast movement on screen), and very little input lag, although LCD input lag can be largely negated. The downsides of CRTs are apparent, though: they’re large, heavy, consume more power, produce flicker, can produce audible, high frequency noise (although age plays into whether one can hear them or not), produce slightly distorted images, and produce harmful electromagnetic waves (in the form of x-rays), which requires that toxic materials such as lead and barium must be used as shielding to prevent detrimental health effects. CRT monitors are also notoriously hazardous to repair, given their large, active electrical coils that can measure upwards of 50,000 volts of electricity.

CRT displays are sometimes still used in medical, simulation, military, and government fields that have embedded the displays into control panels and machinery.

CRT monitors have largely gone out of production, and are rarely sold new (finding a used CRT is fairly easy), but their advantages temporarily lent themselves to some special uses. In regards to gaming, CRT monitors have historically been advantageous to use when gaming competitively due to very little motion blur and very little input lag. That being said, these advantages have faded with the progressive march of TN panels.

TN panels now have low motion blur (especially with lightboost or a similar technology), offer high refresh rates, low response times (1ms GTG in many cases), and are more than adequate even in the world’s most competitive games.

Ultimately, for the vast majority of users, the disadvantages of CRTs aren’t worth their limited gains, especially when TN panels meant for gaming more than adequately satisfy the needs of even competitive gamers.

TN panels have many benefits over the previously popular CRT monitors: lower weight, lower cost to produce, lower power consumption, they’re much thinner, offer clearer pictures, have no realistically achievable resolution limits, offer flexibility in size and shape, and the ability to eliminate flicker.

That being said, TN panels weren"t and still aren’t perfect, and compared to the previously popular CRT monitors, they’ve suffered from limited viewing angles, uneven backlighting, worse motion blur, higher input lag, dead/stuck pixels, and poor display in sunlight.

To be clear, many of these issues have been improved upon, but due to the underlying science of LCD TN panels, cannot be completely resolved. In fact, many of these issues -- like uneven backlighting, motion blur, input lag, and dead/stuck pixels -- are inherent issues across all LCD panel types. Poor viewing angles become a more pressing issue with larger displays, since the viewing angle when viewed straight on increases towards the outside of the monitor, thus causing more color distortion. TN panels do have the advantages of lower response times and higher refresh rates than other panel types/CRTs. TN panels are generally from 60Hz to 144Hz, offering substantially greater fluidity of gameplay with higher frequencies.

TN panels provide a good compromise between CRTs and other LCD panels as their traditionally low response rates, input lag, and high refresh rate make them comparable to CRTs for accuracy; TN panels also have the advantages of offering sharper pictures, widescreen output, lower weight, smaller physical dimensions, and higher resolutions compared to CRTs.

Still, compared to other LCD panels, TN panels suffer from poor viewing angles and worse color reproduction. Ultimately, for most gamers playing somewhat competitively to very competitively, TN panels are a good choice, but for those looking for a prettier and improved color experience, another panel type may be worth considering.

IPS (In-Plane Switching) was created to address the shortcomings of TN panels. IPS panels seek to solve TN panels’ issues of poor color reproduction and viewing angles. In this regard, IPS panels have largely succeed. Not only do they offer a higher contrast ratio (superior blacks), high color accuracy (which leads to IPS panels also generally looking less “washed out”), but IPS panels also have very little color shift when changing the viewing angles.

The tradeoff to this is that IPS panels have slower response times, higher production costs, higher power consumption, and lower possible refresh rates. IPS panels have traditionally been 60Hz, although, as with all monitors, they can be overclocked (results will vary). There have been improvements to IPS panels over the years, and slightly different revisions in the form of E-IPS and H-IPS, but ultimately the differences between these versions are inconsequential to gamers and those not involved in graphic design as a job.

Due to their worse response rates and lower possible refresh rates, IPS panels are generally considered to be worse for competitive gameplay and used more often when color is important, such as graphic design. For gamers who don’t play competitively and prefer breathtaking strolls in Skyrim instead of sweeping scrubs in CS:GO, an IPS panel should be a consideration for the next monitor.

PLS (Plane to Line Switching) are quite similar to IPS panels, so much so that they have the same advantages and disadvantages, with a couple extra minor advantages. PLS is produced by Samsung, who claims that compared to IPS panels, PLS panels have better viewing angles, a 10% increase in brightness, 15% decrease in production costs, increased image quality, and allow for flexible panels. Samsung’s PLS panels have been known to overclock well in monitors such as the QNIX 2710 in particular. Overall, PLS is basically Samsung’s version of IPS, as it is very similar in functionality (and even name). AHVA is also very similar to IPS and PLS, and differentiation between them is rare, although it should not be confused with the next panel type.

VA (Vertical Alignment) panels offer a solid medium between TN and IPS panels. VA was created to combine the advantages of IPS and TN panels, and largely did, although they did so with some compromise. That seems to be a theme in the world of monitors.

Compared to IPS panels, VA panels have the advantage of higher possible refresh rates. Although most are currently 60Hz, there are a few that are above 60Hz. VA has more advantages over TN panels than IPS, with better color reproduction, higher maximum brightness, and better viewing angles. VA panels do have the best contrast ratios of all panel types mentioned, but they also have the worst response times of the monitor technologies covered here. This causes blurring in fast-moving pictures and is disadvantageous to gaming.

For the use of gaming, VA is not the greatest option due to generally higher response time in comparison to other panel types; this slower response causes more motion blur, effectively eliminating its deployment for fast-moving titles. For a general work monitor, VA panels provide high contrast ratios, brightness, refresh rates, good color reproduction, and good viewing angles.

TN panels are another good choice for competitive gamers, as they support higher refresh rates, low response times, decent input lag, and high resolutions. Their bad viewing angles, color reproduction, and slight blurring compared to CRT monitors (due to higher response times) are all disadvantages, ones which cannot be easily fixed.

IPS panels solve the issues of TN panels, with better color reproduction and viewing angles, but do so at the cost of refresh rate and response time. IPS panels are especially useful for those not wanting to play too competitively, but want a beautiful/immersive visual experience. PLS and AHVA are similar enough to IPS to usually not be differentiated.

VA panels provide a good middle ground with better-than-IPS refresh rates and contrast levels, but have worse viewing angles and color production, although generally still better than TN. Response times are VA’s largest downfall, though, being slower than IPS and its variants and TN.

What’s best for you will depend on all of these items. For those wanting to play at a competitive level and who favor FPS or racing games, TN panels are best. Those wanting a more impressive and immersive experience may want an IPS (or similar variant, such as PLS), especially if working on artistic endeavors. Finally, those wanting a general monitor for work might consider a VA panel, although due to their higher response times, they won’t be good for gaming.

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