plasma versus lcd displays factory

Plasma screens contain tiny pockets of gas that get excited when voltage is applied to them, turning them into a state of plasma. In that state, the voltage then strikes electrons of mercury, turning them into ultraviolet (UV) light, which isn"t visible to the human eye. The UV light then passes through phosphor cells; each pixel contains red, green, and blue phosphor cells. Thanks to these phosphor cells, the TV can turn the UV light into colors that are visible on the light spectrum. Essentially, plasma TVs don"t require a light, and each pixel is self-emissive, so how one pixel displays itself is independent of the next pixel.

The pixels aren"t excited continuously, but in short pulses, and some plasma TVs can pulse up to 600 times every second. The naked eye perceives this as flickering, and some people are very sensitive to this. There can also be some advantages to this; since each pixel holds a certain charge, it"s ready to turn on and off as needed, resulting in minimal motion blur. This means that fast-moving content, like in sports or video games, appears smooth.

One of the downsides of plasmas was how they suffered from occasional image retention if they displayed the same image for a long period. So if you watched the news for about an hour, with all of its static displays, then switch channels, you"d still see the outline of the static elements. Eventually, they disappeared, but it could have been particularly annoying. Also, after several years in use, plasmas suffered from permanent burn-in. This happened when the phosphor cells simply stayed stuck in one color and couldn"t display any colors. Unfortunately, there was no way to avoid eventual burn-in, and almost every plasma TV suffered from it.

OLED TVs have similar characteristics to plasmas with their infinite contrast ratio, wide viewing angles, near-instant response time, and to a lesser extent, the risk of permanent burn-in. Since 2012, they"ve replaced plasma as a competitor to LCD TVs, and to learn more about OLEDs and how they differ from LCD TVs, see here.

An LCD screen is composed of two parts: the actual liquid crystal display and a light source at the back of the screen (called backlight). A light diffuser is placed between the backlight and the LCD screen to make the source of light uniform across the screen.

The LCD panel doesn"t emit light by itself, and this is why it needs a backlight; it only acts as a filter to block the light on a per-pixel basis. The backlight is always on, and the pixels in the display rotate to allow light through, creating the colors needed for the image. If the screen wants to display black, the LCD pixels rotate to try to block the light completely. If it wants to display white, it lets all light through. Since the display is only a filter, the blacks will not be as deep as with a plasma screen because an LCD panel will always let a small portion of light through.

There are different types of LCD panels, each with its unique characteristics. Vertical Alignment (VA) panels generally have a high contrast ratio and narrow viewing angles, while In-Plane Switching (IPS) panels have a low contrast ratio with wide viewing angles. You can read about their differences here.

By using a backlight, LCD TVs use much less power than plasmas, which you can read about here. Also, LCD TVs tend to get much brighter than plasmas, making them more suitable for well-lit rooms. There are two main types of backlights used in LCD screens: CCFL and LEDs.

When someone refers to an LCD TV, they usually mean a Cold-Cathode Fluorescent Lamp (CCFL) backlit LCD screen. The first LCD TVs were lit by CCFLs, but they"re extremely rare as of the start of the 2020s. The backlight is a series of light tubes placed behind the screen. These tubes are very similar to fluorescent lamps used in buildings but smaller.

CCFL-backlit LCD TVs were eventually replaced by LED TVs because they cost less, were made thinner, and required less power. Also, LED TVs have more control over their backlight, resulting in vivid colors and better picture quality.

An LED (Light-Emitting Diode) screen is an LCD screen, but instead of having a normal CCFL backlight, it uses LEDs as the source of light behind the screen. Companies label their TVs as LED, even though they"re technically LCD; it can be confusing at times, but if you see an LED TV, you know it has an LCD panel. These TVs are more energy-efficient and a lot smaller than CCFLs, enabling a thinner television screen.

As TV companies attempt to improve their technology, a new type of LED backlighting has emerged: Mini LED. It uses the same traditional LED backlighting behind an LCD panel, except the LED lights are even smaller. This allows for more lights, creating a brighter image and more control over local dimming. Only a handful of Mini LED TVs were produced before 2021, but it now seems that manufacturers are starting to use the technology more often. The Samsung QN90A QLED is an example of a Mini LED TV.

Another technology, Micro LED, is only in its initial phases of development. This doesn"t even have an LCD panel as each LED pixel is self-emissive, similar to OLEDs, but without the burn-in risk. Currently, there aren"t any Micro LED TVs available at the consumer level; Samsung has produced large Micro LED TVs (over 100 inches), and they"re very expensive. However, we may begin to see Micro LED technology in the consumer TV market soon.

Plasma and LCD each present advantages and disadvantages when it comes to picture quality. Plasma TVs generally offer better contrast, wider viewing angles, and improved response times, while LCD TVs get much brighter and have better reflection handling. LCDs also cost less and can be much thinner, which are two of the main reasons why they took over the market share from plasmas in the mid-2000s. Plasma TVs are now extinct, and although OLEDs share many of the same characteristics, LED-backlight LCD TVs are now the norm, and it"s likely your next TV purchase will have an LCD panel.

Plasma TV production ended in 2015. However, they are still being used and sold in the secondary market. As a result, it"s helpful to understand how a Plasma TV works and how it compares to an LCD TV.

Within each cell, a narrow gap that contains an insulating layer, address electrode, and display electrode, separates two glass panels. In this process, neon-xenon gas is injected and sealed in plasma form during the manufacturing process.

When a Plasma TV is in use, the gas is electrically charged at specific intervals. The charged gas then strikes red, green, and blue phosphors, creating an image on the screen.

Each group of red, green, and blue phosphors is called a pixel (picture element — the individual red, green, and blue phosphors are called sub-pixels). Since Plasma TV pixels generate their light, they are referred to as "emissive" displays.

Plasma TVs can be made thin. However, even though the need for the bulky picture tube and electron beam scanning of those older CRT TVs is not required, Plasma TVs still employ burning phosphors to generate an image. As a result, Plasma TVs suffer from some of the drawbacks of CRT TVs, such as heat generation and possible screen burn-in of static images.

LCD crystals do not produce light, so they need an external source, such as fluorescent (CCFL/​HCFL) or LEDs, for the picture created by the LCD to become visible to the viewer.

Unlike a Plasma TV, since there are no phosphors that light up, less power is needed for operation, and the light source in an LCD TV generates less heat than a Plasma TV. There is no radiation emitted from the screen.

Plasma TVs are more vulnerable to burn-in of static images. However, this problem diminished over the years due to "pixel orbiting" and related technologies.

Potentially shorter display lifespan. Early models had 30,000 hours or 8 hours of viewing a day for nine years, which was less than LCD. However, screen lifespan improved and 60,000-hour lifespan rating became the standard, with some sets rated as high as 100,000 hours, due to technology improvements.

Not as good at tracking motion (fast-moving objects may exhibit lag artifacts). However, this has with the implementation of 120Hz screen refresh rates and 240Hz processing in most LCD sets, but that can result in the "Soap Opera Effect," in which film-based content sources look more like a videotape than film.

Narrower effective side-to-side viewing angle than Plasma. On LCD TVs, it is common to notice color fading or color shifting as you move your viewing position further to either side of the center point.

Although LCD TVs do not suffer from burn-in susceptibility, single pixels can burn out, causing small but visible, black or white dots to appear on the screen. Individual pixels are not fixable. Replacing the whole screen is the sole option if the pixel burnout becomes unbearable.

An LCD TV was typically more expensive than an equivalent-sized (and equivalent featured) Plasma TV. However, that is no longer a factor, since companies have ceased manufacturing Plasma TVs.

Manufacturers chose to incorporate 4K resolution only in LCD TVs, using LED back and edge-lighting, and, in the case of LG and Sony, incorporating 4K into TVs using OLED technology.

Although it was possible to incorporate 4K resolution display capability into a Plasma TV, it was prohibitively expensive. When the sales of Plasma TVs started declining, TV makers decided against bringing consumer-based 4K Ultra HD Plasma TVs to market, which was another factor in their demise. The only 4K Ultra HD Plasma TVs manufactured were for commercial application use.

If you"re in the market for a flat-screen television, then you probably have one big question you want answered: plasma vs. LCD; which one is right for you?

The two different camps of flat-panel display standards will, of course, gladly spruik the advantages of their own standard and the deficiencies of the other. But what type of display — plasma or LCD — is actually better? And which will give you more bang for your buck?

Plasma and LCD panels may look similar, but the flat screen and the thin profile are where the similarities end. Plasma screens, as the name suggests, use a matrix of tiny gas plasma cells charged by precise electrical voltages to create a picture. LCD (liquid crystal display) screens are in layman"s terms sandwiches made up of liquid crystal pushed in the space between two glass plates. Images are created by varying the amount of electrical charge applied to the crystals. Each technology has its strengths and weaknesses, as you"ll read below.

It"s not what"s happening behind the screen that"s important — it"s how the screen performs as a television that matters the most. In that regard, both plasma and LCD TV sets produce excellent pictures, and the differences between them aren"t as pronounced as they used to be. While the latest plasmas are particularly good, LCD sets are quickly catching up in terms of quality, with advances like LED backlighting.

For basic home cinema-like usage, plasma screens have a slight edge over LCDs. This is because plasma screens can still display blacks more accurately than LCDs can, which means better contrast and detail in dark scenes. The nature of LCD technology, where a backlight shines through the LCD layer, means that it"s hard for it to achieve true blacks because there"s always some light leakage from between pixels. As LCD/LED technologies such as polarising filters and dynamic backlights improve, the quality gap between the technologies grows narrower.

Apart from better contrast due to its ability to show deeper blacks, plasma screens typically have better viewing angles than LCD. Viewing angles are how far you can sit on either side of a screen before the picture"s quality is affected. You tend to see some brightness and colour shift when you"re on too much of an angle with LCDs, while a plasma"s picture remains fairly solid. Plasmas can also produce richer, more natural colours, due to both light leakage and to a limit on the hues that LCD can reproduce.

Plasma pundits will also tell you that some LCD screens have a tendency to blur images, particularly during fast-moving scenes in movies or in sport. While that was true for older generation LCD screens, newer models have improved significantly — so much so that the differences in performance between LCDs and plasmas in this regard is almost negligible. (While the pixel response time, measured in milliseconds (ms), can give you some indication of an LCD"s performance with fast-moving scenes, it"s not always reliable.)

Traditionally, the biggest advantage that plasmas have had over their LCD cousins is price, particularly in the large screen end of the market. Depending on the resolution, plasma is still able to beat most equivalently priced LCD screens. Plasmas currently sold in Australia generally run between 42 and 65 inches wide, with the cheapest 1024x768 standard-definition 42-inch selling for under AU$1000.

At present, the mainstream plasma size is 50 inches, but sizes of 60 inches and above are becoming more common. At these sizes, plasmas tend to be two thirds or less than the price of the equivalent LCD, due to the high manufacturing cost of LCD panels.

Apart from becoming increasingly price-competitive, LCD has the edge over plasma in several other key areas. LCDs tend to have a higher native resolution than plasmas of similar size, which means more pixels on the screen.

LCDs also tend to consume less power than plasma screens, with some of the newer "Eco" LCD panels able to use half of the power than equivalent plasmas, with the trade-off being lower brightness.

In terms of bulk, LCDs are also generally lighter than similar-sized plasmas, making it easier to move around or wall-mount. This is because LCDs use plastic in their screen make-up, whereas plasmas tend to use glass.

LCD pundits point to the belief that LCDs have a longer lifespan than plasma screens. While this may have been true of earlier plasma models — which dropped to half-brightness at 20,000 hours — many modern plasmas have the same 60,000-hour lifespan as LCDs. This means that both types of TVs will last for almost seven years if left on 24 hours a day.

You might have also heard that plasmas suffer from screen burn-in, an affliction not commonly associated with LCDs. Screen burn-in occurs when an image is left too long on a screen, resulting in a ghost of that image "burned in". Newer plasmas are less susceptible to this, thanks to improved technology and features such as screensavers, but burn-in can still be a problem. However, after a few days most burnt-in images will fade — they are no longer permanent.

If you"re in the market for a big-screen television — and we"re talking 50 inches and above — then we"d suggest plasma as a safe bet. Plasmas give you more bang for your buck at the big end of town, and while LCDs can give you better resolution, plasma still has the edge in terms of picture quality.

At the smaller end of things (17- to 42-inch TVs), LCD is the only way to go if you want something slim and tasteful. And the best thing is that LCDs are getting cheaper all the time.

There has also been a lot of debate surrounding use in bright environments versus dark, cinema-like conditions. The traditional wisdom is that LCD performs better during the day due to its backlighting system, and that plasma works best in a dark environment, as it uses a glass front. Nonetheless, products like the non-reflective glass plasmas and LED-backlit LCD panels with their better blacks completely turn this logic on its head.

In the past couple of years, several new features have cropped up, but the most pertinent to this discussion is 3D. While it"s possible to manufacture a 3D screen with both LCD technology and plasma, based on our extensive testing, a plasma screen is the best at producing 3D images and reducing the artefact known as crosstalk, or ghosted imaging. Be aware that there is still very little content available in 3D, and that the technology is still evolving. Buy a set for its 2D abilities first, and then consider 3D.

While most screens are now full high-definition (1080p), resolution is a consideration when you"re looking at budget screens. Budget LCDs and plasmas feature either 1366x768 or 1024x768 (720p) resolutions. If you"re buying a screen that"s 42 inches or larger, though, there"s now no reason to get anything less than 1080p.

Plasma TVs contain tiny pockets of gas, and when a voltage is applied to them, they turn into a plasma state. The voltage then strikes the mercury within the plasma to emit ultraviolet (UV) rays, which pass through phosphor cells to produce an image. Each pixel in the TV contains three phosphor cells: red, green, and blue, and these three colors combine to produce a color. Essentially, plasma TVs don"t require a backlight, and each pixel is self-emissive as it produces its own light.

Unlike plasma TVs, LCD TVs use a backlight. Initially, LCD TVs used Cold-Cathode Fluorescent Lamp (CCFL) as their backlight. These are long tubes that are placed horizontally across the screen behind the LCD panel. When the light is turned on, it applies a voltage to the pixels, which makes them rotate a certain way to allow light through and produce an image. When it wants to display black, the pixels are rotated to create an opaque screen so that light doesn"t get through. This is what makes them different from plasma TVs because each pixel isn"t self-emitting.

Light-Emitting Diode (LED) TVs are the same as traditional LCD TVs, but instead of using CCFL backlights, they use many smaller LED lights. It produces an image the same way as a regular LCD TV because it still uses an LCD panel, but it has more control over the backlighting. The LEDs can be placed along the edges, which is called edge-lit LED, or all over the back panel, which is either called direct LED or full-array backlighting. You can see the differences between LCD and LED TVs below.

It"s also important to note LED is simply a marketing term used by manufacturers to describe their backlight. They"re still technically LCD TVs, but since calling them LED is so common now, we even label them as LED, and we"ll continue to do so throughout this article.

Plasma and LED TVs each present their own advantages and disadvantages in terms of picture quality, price, build, and availability. It"s generally thought that plasma produces a better picture quality due to their superior contrast ratio, but LED TVs became more popular because of other factors, like a lower cost and greater availability.

Below you can see the differences in picture quality between two older TVs from 2013. It"s clear the plasma was better at the time, but LED TVs have also gotten better since then, so picture quality has greatly improved.

Contrast ratio was one of the main advantages and selling points of plasma TVs. Since each pixel emitted its own light, it simply turned itself off when it wanted to display a black image. This allowed the TV to display very deep blacks, but because there was always a bit of charge left in the plasma, it still wasn"t a perfect black level.

On the other hand, LED TVs can"t achieve a perfect black level because the backlight is always on. However, technology has evolved to greatly improved the contrast of LED TVs, even to the point where it"s also as good as what plasma once was. There are two main types of LCD panels in TVs: Vertical Alignment (VA) and In-Plane Switching (IPS). VA panels produce a better contrast than IPS, and high-end TVs also have local dimming features that turn off certain zones of the LED backlights. Still, you won"t get a perfect black level, but most modern LED TVs produce such deep blacks that even in a dark environment it looks like perfect black levels. For reference, plasma TVs had a max contrast of about 4,000:1, according to DisplayMate.com, but some recent LED TVs can reach a contrast of over 20,000:1 with local dimming enabled, like the Samsung QN90A QLED.

LED TVs are a clear winner here, and it"s one of the reasons why they surpassed plasmas in terms of popularity. LED TVs get significantly brighter, so they can fight glare from light sources easier. Additionally, plasma TVs had to use glass on their front panel, which caused intense glare if you had any lamps or windows around the TV. LED TVs can use a coating on their glass panel to help reflect and diffuse light, making it a better choice for well-lit rooms.

Plasmas were designed for dark-room viewing, but since most people don"t have dedicated home theater setups and often watch with a few light sources around, they weren"t that useful. As you can see below, the plasma TV had pronounced reflections, to the point where it"s even hard to see the image, and instead you"re watching yourself watch TV. Reflections are still noticeable on an LED TV, but at least you can see the image.

Pixels on plasma TVs emitted light in all directions, creating extremely wide viewing angles, much better than most LED TVs. This means that the image remained accurate when viewing from the side, which was great for watching sports or a show with a few people. Out of the two main panel types for LED TVs, IPS has wider viewing angles than VA panels, but it"s still not as good as plasma.

TV manufacturers have tried different technologies to improve viewing angles on VA panels. Samsung has an "Ultra Viewing Angle" layer, and Sony uses their "X-Wide Angle" technology to increase the viewing angles, both at the cost of a lower contrast ratio. It"s still not as good as plasma, but they"re wide enough for watching TV in a fairly large seating area.

Below you can see the differences in viewing angles between a plasma and a VA panel. These TVs were tested on different test benches, so you shouldn"t directly compare the videos, but we included them to give you an idea of how each technology affects the viewing angle.

Plasma TVs were great for motion handling, like with sports and video games due to their quick response time. Since each pixel had to retain a certain charge at any given moment, it was ready to display an image almost instantly. This meant fast-moving scenes looked crisp and smooth, with no motion blur behind them. However, for LED TVs, it can be a toss-up; some lower-end models have a slow response time that causes motion blur, while other high-end TVs have a really fast response time.

In terms of refresh rate, plasma TVs had a higher internal refresh rate, up to 600Hz, while LED TVs tend to be 60 or 120Hz. However, the refresh rate depends on the content, and since most content doesn"t go past 120 frames per second, having a higher refresh rate TV isn"t very useful.

Screen uniformity is another area where plasma TVs win. Since they didn"t have a backlight, they could evenly control each pixel. LED TVs can suffer from uniformity issues, like darker edges or Dirty Screen Effect in the center, because the backlight output may not be even across the panel. However, this is only really noticeable when watching content with large areas of uniform color, like a hockey or basketball broadcast, or if you"re going to use the TV as a PC monitor. It shouldn"t be noticeable with other types of content, and since uniformity can vary between units, you shouldn"t worry about it too much.

One of the reasons plasma TVs didn"t last too long at the top of the TV world is because of their risk of temporary image retention and permanent burn-in. Plasmas lose their brightness over the years, and in the worst case, would have permanent burn-in with certain colors staying on the screen, as you can see here. Even after watching content with static elements, like the news, for an extended period, the outline of the static elements would stay on the screen for a few minutes after changing the channel.

These problems are particularly annoying, especially if you watch a lot of TV. There was no way to help reduce this issue, and after a few years, depending on how much you used the TV, your plasma would need replacing. LEDs don"t suffer from this same permanent burn-in, so you won"t have to worry about replacing your LED TV down the line because of burn-in.

Due to their different technologies, LED and plasma TVs are built differently. Plasma TVs tended to be heavier and thicker because the panel itself was larger. Although plasmas were the first flat-screen TVs available at a consumer level at the end of the 20th century, LCD TVs quickly became even thinner, easier to package, and lighter to carry from the store to your house. These days, LED TVs are as thin as 1", like the Samsung QN85A QLED.

Plasma TVs also required a lot of power to work and tended to get very hot. With the growth of environment-friendly consumer practices, it became clear LED TVs would win out since they required a lot less electricity, and in a way were better for the environment.

Both plasma and LED TVs were made with larger sizes, but LED had a slight advantage because they were also made in displays smaller than 32 inches, like with monitors. Although small TVs are rare now, you can still find a basic 28 or 32 inch TV for a kitchen or bedroom with an LED panel. Plasma TVs weren"t made that small. LED TVs also cost less to produce and are cheaper on the market, so at the end of the day, the lower cost drove LED sales.

When 4k TVs started to become the norm over 1080p and 720p TVs in the mid-2010s, manufacturers started to produce 4k LED TVs, while plasma TVs were stuck at 1080p. This presented a major advantage for LED TVs, as a higher resolution helps create a crisper image, and this essentially was the nail in the coffin for plasma TVs. Since manufacturers were focused on making 4k LED TVs, plasma TVs became less available, and by 2014, Panasonic, LG, and Samsung all stopped their plasma production. LED TVs surpassed plasma sales in 2007, and they haven"t looked back since.

There were a few other problems that contributed to the decline of plasma TVs. First of all, plasma TVs didn"t work at high altitudes because of the change in air pressure with the gasses inside. They would create a buzzing noise, and the image wouldn"t look the same, so this could have been problematic if you lived at a high altitude. LED TVs can be used at any altitude; you shouldn"t use them in extreme cold or extreme heat, but this is standard practice for any electronic, and temperature is easier to control than your altitude. Also, plasma TVs emitted a radio frequency that could have interfered with other devices around, like if you had a radio in the same room. Each of these issues are simply inconvenient for most people.

The simple answer is yes, but it doesn"t mean you should go out tomorrow and buy a new TV just because you read this article. If you aren"t experiencing any issues with your plasma, then you probably don"t need to replace it right away. However, if you notice your plasma is starting to show some signs of permanent burn-in, it"s probably a good idea to get a new TV before the burn-in becomes worse.

There could be other advantages if you upgrade your TV, like technological advancements and a higher 4k resolution. Modern TVs come with a built-in smart system, which isn"t something that most plasmas had, and this allows you to directly stream your favorite content without the need for an external streaming device. As mentioned, LED TVs aren"t very costly, and you can easily find the best 4k TVs for under $500.

At the same time that plasma TVs met their end, OLEDs grew from the ashes of their predecessor. After LG released the first commercially available 55 inch OLED in 2012, it soon competed with LED TVs. OLED, which stands for Organic Light-Emitting Diode, is different from plasma, but shares many of the same characteristics, while also avoiding some of plasma"s downfalls.

OLEDs use self-emissive pixels, but what sets them apart is how the pixels completely shut off, creating an infinite contrast ratio and perfect black uniformity. This is an improvement from plasma because it was never able to reach those perfect blacks. OLEDs also have wide viewing angles and a near-instant response time like plasmas. Sadly, they don"t get extremely bright, but they"re still better for well-lit rooms than plasma because they get a bit brighter and have much better reflection handling. Also, OLEDs have the same burn-in risk as plasma, but this only happens with constant exposure to the same static elements, and we don"t expect it to be a problem for people who watch varied content.

Another advantage for OLED is how thin they are, especially compared to plasma, and they aren"t as heavy. For example, the LG GX OLED is a TV designed to sit flush against the wall and it"s only 0.94" thick!

Although plasma TVs once dominated the TV market for a short time at the turn of the 21st century, their disadvantages outweighed their advantages, and LED-backlit LCD TVs soon held the market share of sales. There were a few reasons for this, like burn-in issues, low peak brightness, and a thick and heavy design compared to LED TVs. Despite plasma TVs" superior overall picture quality, improved contrast, and very quick response time, it wasn"t enough to convince consumers to keep buying them once 4k LED TVs became readily available. If you still have a plasma, it"s likely you"ll need to replace it within the next few years, and you"ll probably buy a new LED TV.

When deciding whether to use plasma or liquid crystal diode (LCD) displays for your applications, you need to consider many factors. Both provide brilliant colour, sharp text contrast, and crystal-clear images. But the way in which plasma and LCD screens process and display incoming video/computer signals is markedly different.

Both plasma and LCD technology provide stark enough contrasts to make displays sharp and pleasing. But when it comes to contrast output, plasma technology outperforms LCD screens. Some plasma displays have a 3000:1 contrast ratio, which is the measure of the blackest black compared to the whitest white. LCDs use electric charges to untwist liquid crystals, thereby blocking light and emitting darker pixels. Despite this process, LCD displays don’t produce more than a 1000:1 contrast ratio.

Pixels contain enough information to produce every colour in the spectrum. Because plasmas use each and every pixel on their screens, colour information is reproduced more accurately. Plasma screens display moving images with remarkable clarity, though burn-in can be an issue. For displays with lots of light and dark imagery, plasma panels provide excellent performance with their high-contrast levels, colour saturation, and overall brightness.

LCD displays, on the other hand, manipulate light waves and reproduce colours by subtracting colours from white light. Though this makes it more difficult to maintain colour accuracy and vibrancy compared to plasma screens, LCDs have an advantage with their higher-than-average number of pixels per square inch. These additional pixels make LCD technology better at displaying static images from computers or VGA sources in full-colour detail. Plus, there’s no flicker and very little screen burn-in.

With LCD screens, there are essentially no parts to wear out. LCD screens last as long as their backlights do, with displays lasting, on average, 50,000–75,000 hours. That’s why LCD screens are especially good for long-term applications, such as digital signage or displays that require around-the-clock use.

Plasma screens, however, use a combination of electric currents and noble gases (argon, neon, and xenon) to produce a glow, which in turn yields brilliant colour. The half-life of these gases, however, is only around 25,000 hours. The glow they produce grows dimmer over time.

Plasmas light every pixel on the screen, making the brightness on the screen consistent and giving plasmas the edge when it comes to viewing angles. In fact, plasma screens have as much as a 160° viewing angle compared to LCDs. This makes viewing the images on the screen easier to see from a variety of angles. In doing so, however, plasmas consume much more power.

LCDs display at 130–140° angles, but their use of fluorescent backlighting requires much less power to operate than plasmas. This also makes LCDs less prone to burn-in or ghosting of images.

Many people become confused by what type of flat-panel TV—plasma or LCD—they should purchase. The technology you pick will depend on a number of factors, including screen size, viewing conditions, price and, ultimately, your perception of which one looks the best.In terms of size, LCD flat-panels start as small as 10 inches and go up to 65 inches. Sets above 52 inches, however, can get expensive. Unlike smaller LCD TVs which typically have old-style 4:3 aspect ratios, all plasmas are widescreen. Plasmas start at 37 inches and go up to 103 inches.

LCDs are available in smaller sizes, allowing them to go where a 37-inch plasma will not fit. They also provide incredibly bright images when viewed on center. If you plan on watching your TV in a room with a lot of light, LCD has the edge over plasma, both with its bright picture and its special surface coatings that reduce room reflections.

LCDs generally have slower video response times than plasmas, which is noticeable primarily on sports and fast action scenes. They also have a narrower viewing angle, meaning that as you move off center, the image contrast and brightness drop off. Most LCD panels (as well as plasmas) are factory preset to stand out in the very bright lighting at most stores. When you get them home and out of the box, however, they are way too intense. You should change the menu setting from factory preset (usually Vivid) to Movie, Cinema or Standard (depending on your set) and lower the contrast (also called Picture Control) to the halfway point for the best picture.

If your television is going to be in room with normal lighting, plasma will provide superb image quality, dark blacks and bright whites over the widest viewing angle. However, if you need a screen below 37 inches, LCD is really the only choice available. Enclosed patios, really bright rooms with skylights or untreated windows, and sunny kitchens are all excellent spots for LCD displays of all sizes.

Plasmas have wide viewing angles, meaning you can sit off-center and still see a very good picture. They have high contrast ratios, excellent color, deep blacks, fast response times for viewing scenes with a lot of motion such as sports, and generally lower prices than LCDs above 42 inches. Today’s plasmas have a long life expectancy. Many of the top tier brands are now rated at 60,000 hours, which is equal to over 16 years of use when operating the set 10 hours a day, every day.

Plasma disadvantages are few. In the early days, the most common criticism was that they suffered from “burn-in,” meaning that when a static image such as a video game logo is on the screen for too long, its shadow may linger even after it’s gone. Burn-in really is the uneven wear of the phosphors within the plasma panel. The risk of burn in has been greatly reduced by the set makers and can be minimized with a simple precaution. Like with LCD, upon unpacking and connecting the set, change the “picture mode setting” from factory preset (usually Vivid) to Movie, Cinema or Standard (depending on the TV) and lower the contrast (also called the “picture control”) to about one half level for the best picture.

In the age of High Definition TV size matters most. What many shoppers and salesmen don’t realize, buying a screen that is too small or sitting too far away from the display will rob you from seeing all the high definition the set has to offer, thereby wasting your money. HDTV provides a more immersive viewing experience than old style 4:3 standard definition TV, as well more picture detail than you have ever seen on a home display. In order to fully resolve all the detail within HDTV, you must sit in the optimum viewing range. Sit further and your eyes will not be able discern all the detail within the image. There are three levels of resolution for flat TVs. The first level is not HDTV; it is called Enhanced Definition at 480 vertical lines. The two classes of HDTV grade displays are 720p/768p with the display showing either 720 lines (or 768 lines) of resolution from top to bottom and 1080 (i or p), the highest quality HDTV display, with 1080 lines of resolution. For ED sets you can sit as far as 3.4 times the screen diagonal to see all detail. This means up to 142.8 inches (just under 12 feet) from an ED (480p) 42” set. Using the same size screen a 720p/768p you need to be at a viewing distance of at 2.3 times the screen size or closer, which is equal to 96.6 inches or eight feet. With a 1080 (i or p) 42inch set you should at no more than 1.55 times the screen size or 65.1 inches (just under 5½ ft.) to distinguish ever pixel within the image.

There are a number of high-definition LCD and plasma displays that are sold without tuners. These are called “HD monitors,” and, like a computer monitor, they are useless without a signal source. Most monitors come with speakers, but some do not. With an HD monitor, you must connect it to a high-definition source to receive a true high-definition picture. You have three good high def options— over-the-air tuner box, cable box and satellite. Do not confuse “digital cable” for high definition. Make sure your cable provider is supplying you with a high-definition signal. An integrated HDTV has a built-in digital tuner and can receive over-the-air HD broadcasts.

LCD – The big myth, the liquid will leak out of LCD panels. This is not true; all LCD panels are sealed and never need to be refilled. You should always handle the panel by its frame, never lie the panel face down and never press on the screen. The front glass is very thin (much thinner than the front glass found on Plasma TVs) and cracks quite easily.

Plasma – The big myth, the Plasma gas will leak and need to be recharged. Like LCD, plasma panels are factory sealed and won’t leak or ever need to have the internal gases refilled.

Another myth, Plasma TVs consume more electricity than LCD. Fact, in recent HD GURU tests, plasma TVs used fewer watts of electricity than comparably sized LCD flat panel televisions.

LED HDTVs (properly known as LED-backlit LCD TVs) use light emitting diodes (LEDs) as a backlight for the LCD. Some of this light is blocked by vertical or horizontal liquid crystals, creating an image. These should not be confused with actual LED or OLED TVs.

Plasma HDTVs create images using phosphors, tiny plasma containers placed between two sheets of glass. These emit ultraviolet light at colored spots of phosphor on the screen, which then glow to create the picture.

Plasma TVs tend to have deeper blacks, and stabler color over the screen"s breadth from a variety of angles, leading to smoother, more natural images than seen on LED-lit LCD screens. Plasma screens also show crisp, fast motion without blur or ghosting.

According to CNET, LED-lit LCD TVs are the brightest available. They are capable of 100 footlamberts, although this is bright enough to cause eye fatigue in a dark room. Plasmas are less bright, so they might be more difficult to see in a bright room, and will dim over time.

Plasma screens normally range from 42 inches to approximately 65 inches. Panasonic also offer some larger models, including a 152 inch TV. Plasma screens also weigh more than LED-lit LCD screens.

Plasma TVs are less energy efficient than LED-lit LCD TVs. According to Which magazine, a 42 inch screen LED-lit LCD TV will use an average of 64 watts, while an average 42 inch Plasma TV uses 195 watts.

HDTVs are generally highly reliable. LED-lit LCD TVs are considered to have a lifespan of 100,000 hours, although they have not been in use long enough to have extensive information on their long-term reliability.

According to PC World, users of Panasonic’s plasma TVs rate them highly reliable, with very few serious problems. In 2010, just 1 in 20 Panasonic users reported a major problem with their TVs. Older plasma TVs have a lifespan of 20,000 hours, although some newer TVs have up to 60,000 hours.

LED-lit LCD TVs are typically more expensive than Plasma TVs. For example, on Amazon.com a Panasonic LED-lit LCD 42 inch TV was listed for $900 while a Panasonic Plasma 42 inch TV costs $600.

LCD screen TVs are the most popular, followed by LED-backlit screens (which are also LCD screens, by the way). Plasma screens are less popular and more commonly available in larger sizes.1,274 LCD TVs

All major TV manufacturers sell LED-lit LCD TVs. Panasonic focuses its TV range on the Plasma TV, while other brands, such as LG and Samsung, only produce a few models, and some, such as Sony and Toshiba, no longer produce Plasma TVs at all.

Editor’s Note:TV manufacturers stopped making plasma TVs in 2014. To learn about current TV technologies, please read our TV buying guide or our OLED vs LED article. Thanks for visiting Crutchfield.com.

Considering a flat-panel TV? The latest LED-LCD and plasma TVs deliver outstanding picture quality, and both display technologies get a little better every year. Each type has a different set of strengths that make it more suitable for certain viewing situations.

Some people mistakenly believe that so-called "LED TVs" use a new display technology. The term is frequently used by TV manufacturers and many retailers, but LED TVs are just LCD TVs that use an LED backlight instead of a fluorescent one. LED-LCD TVs generally have better contrast and more accurate colors than fluorescent-backlit models, and the LEDs are also very energy efficient.

At this point (9/13), nearly all LCD TVs from major brands use LED backlights, except for very basic models and TVs designed for outdoor use. For more information, see our video on LCD backlighting.

If you poke around the Internet you"ll find a ton of information (and some misinformation) about today"s flat-panel TVs. The chart below provides a quick comparison of plasma and LED LCD. Display

Plasma Pros: excellent contrast and black levels; effortless motion; uniform illumination over the entire screen area, good picture depth; often priced lower than LED-LCD models with similar screen size and features

Cons: limited screen sizes: 42"-65"; some models not as bright as most LED-LCD TVs; not as energy-efficient as LED-LCDs and typically generate more heat; a plasma panel is usually a bit heavier and thicker than an LED-LCD panel

LED-LCD Pros: models with advanced local dimming backlights can have black levels rivaling plasma; LED-LCD panels are thin and lightweight — especially models with edge-lit backlights; this is the most energy-efficient display technology

There are two basic ways to increase a TV"s picture contrast: either make whites look brighter, or blacks look blacker. LED-LCD TVs are typically brighter than plasmas, while plasmas are known for producing deeper black levels. And for that reason we have tended to recommend LED-LCD TVs for use in rooms where the TV is competing with lots of other light sources in the room, like windows or lamps. Plasma"s blacker blacks can be best appreciated in a room with the lights dimmed or darkened.

The reason plasmas excel at picture contrast is that each pixel — actually each subpixel — is self-illuminated, allowing very precise, controlled lighting. On the LED-LCD side, higher-performing models use sophisticated LED backlighting that can switch clusters of LEDs on and off based on the picture content. The general name for this ability is "local dimming." Originally, local dimming only referred to expensive high-end models that used a full-array backlight — a grid of LEDs that covered the back of the screen. Only a couple LED-LCD TVs still employ that technology, and local dimming is used to describe edge-lit displays that have a less precise but still effective form of dimming.

Viewing angle limitations are more of an issue for LED-LCD TVs than for plasmas. All LCDs use a backlight, and the LCD pixels act like shutters, opening and closing to let light through or block it. This shutter effect causes increasing variations in picture brightness as viewers move further off axis.

What you should know about motion handling: Motion handling has always been a strong point for plasma TVs. Because of the way plasma TVs create the picture, there"s no lag or ghosting, and motion looks very natural and crisp. So if clear, true-to-life on-screen motion is a high priority for you, you should definitely consider a plasma.

For LED-LCD TVs, motion handling has been more of a challenge because of the way they create the picture. But many of today"s LCD TVs are better equipped to display fast motion without blur. If you want smoother motion with an LCD, look for a model with a 120Hz or 240Hz refresh rate. These sets include sophisticated processing that can virtually eliminate motion blur.

To watch 3D TV, you"ll need a TV with a screen capable of displaying 3D video — it can be a plasma or LED-LCD. You"ll also need compatible 3D glasses, either "active" or "passive" to match the type of 3D TV you have. For the most theater-like 3D experience, you"ll need a source of 3D video, like a 3D Blu-ray player or 3D channels from your cable or satellite TV provider. But if you don"t have a source of 3D content, you can still get a taste of 3D because nearly all current 3D TVs include built-in 2D-to-3D conversion. The feature adds a bit of 3D-like depth to regular 2D material. For more info, see our intro to 3D, watch our video about 3D TV, or check out our in-depth 3D TV FAQ.

TV makers don"t mention longevity much anymore, but the last time we checked, both plasma and LED-LCD TVs from major brands have a rated lifespan of 100,000 hours. And that doesn"t mean that if your TV reaches the 100,000-hour mark it will simply stop working. That number represents the estimated time when the TV"s display panel will produce a picture that"s only half as bright as when it was new. After the "half brightness" point the TV will still be usable, just somewhat dimmer.

But logging 100,000 hours of use takes a longtime. If you were to watch for 6 hours a day, every day, it would take over 45 years! There are other parts in a TV other than the illumination component that could fail over time, but over the years the TV manufacturing process has grown more precise and consistent. The bottom line is that a new LCD or plasma TV should last at least as long as a typical tube TV.

You do a lot of daytime viewing in a room with windows lacking blinds, curtains or drapes. An LED-LCD"s bright picture will still look crisp and colorful in bright light; some LCD screens also resist glare.

An LCD TV is sometimes referred to as a "transmissive" display. Light isn"t created by the liquid crystals themselves; instead, a light source behind the LCD panel shines through the display. A diffusion panel behind the LCD redirects and scatters the light evenly to ensure a uniform image.

The multi-layered structure of a typical LCD panel. Because they use red, green and blue color filters in place of phosphor dots, LCD TVs are completely immune to screen burn-in.

LCD TVs use the most advanced type of LCD, known as an "active-matrix" LCD. This design is based on thin film transistors (TFT) — basically, tiny switching transistors and capacitors that are arranged in a matrix on a glass substrate. Their job is to rapidly switch the LCD"s pixels on and off. In an HDTV"s LCD, each color pixel is created by three sub-pixels with red, green and blue color filters.

An important difference between plasma and LCD technology is that an LCD screen doesn"t have a coating of phosphor dots (colors are created through the use of filters). That means you"ll never have to worry about screen burn-in, which is great news, especially for anyone planning to connect a PC or video game system.

A plasma TV is sometimes called an "emissive" display — the panel is actually self-lighting. The display consists of two transparent glass panels with a thin layer of pixels sandwiched in between. Each pixel is composed of three gas-filled cells or sub-pixels (one each for red, green and blue). A grid of tiny electrodes applies an electric current to the individual cells, causing the gas (a mix of neon and xenon) in the cells to ionize. This ionized gas (plasma) emits high-frequency UV rays, which stimulate the cells" phosphors, causing them to glow the desired color.

Because a plasma panel is illuminated at the sub-pixel level, light output is very consistent across the entire screen area. Plasmas produce the widest horizontal and vertical viewing angles available — pictures look crisp and bright from virtually anywhere in the room.

Because plasma TV screens use a phosphor coating like CRT-based TVs, the possibility of screen burn-in exists, though it"s unlikely to happen with current models. To reduce the chance of burn-in, be sure to follow the manufacturer"s recommendations on setup and use.

Thinner, bigger, faster, cheaper. Direct view LCD screens are just starting to break the size barrier that once held them back (with some models getting as large as 100+" though don"t expect volume shipments) and it will be up to the manufacturing plants to convert or expand to the point where these larger screens become affordable and economical to produce. LCDs are not yet the best for black levels, but they are getting better due to LED backlighting and the "blur" effect, where the pixels cannot refresh fast enough for the screen motion, is all but extinct in newer 120Hz models.

Plasma screens are sometimes viewed as a wonder of the modern world, and most of their attention comes from their flat presentation and large screen sizes. They are able to be produced in sizes up to 103" (don"t look for mass production of this size, however) and yield a very nice picture. The downside is that they are power-hungry (not to be confused with the environmentally-friendly LCD screens). You may enjoy watching commercials with plasma screens hanging on the ceiling, but even Philips will tell you that their screens do much better hanging on a wall or placed on a stand.

Extinction. While it has taken far longer than originally estimated, we maintain that LCD panels are on a trend to become a commodity. This year, Pioneer announced it is leaving the plasma panel manufacturing business and taking on LCD panels from Sharp. The LCD manufacturing process is getting better, additional manufacturing plants open up each year to turn out more and more panels and performance is increasingly getting better. Add to that the low cost of manufacturing and additional technologies coming on board and you have a tough road ahead for plasma. Plasma displays are indeed competing in terms of longevity, brightness, (true) contrast ratio, power consumption and burn-in. Their black levels and color saturation are very impressive. Due to these advancements it is very likely that plasma and LCD will maintain parallel development for some time. As LCD displays become thinner, cheaper, faster and more competitive, however, plasma will become obsoleted.

1080p has also finally made in-roads with plasma. Beginning with Hitachi (who unlike many other companies actually demoed a working unit at last year"s CEDIA) 2007 seems to be the year of 1080p plasma technology - albeit at a price.

Buying a TV and wondering what type of display tech is better? We’ve got the lowdown for you in this LCD vs Plasma buying guide. These two technologies produce images through vastly different processes, and each comes with a different set of pros and cons. So before we dive head first into which type of screen is better and why, it’s helpful to understand the technology behind each type of screen. Don’t worry, it’s not as complex as you might think.

LCD is short for liquid crystal display, and while the TVs made with this tech come in a few different varieties (namely CCFL-backlit and LED-backlit), the panels they use are the same. LCD panels are typically composed of two sheets of polarized material with a liquid crystal solution between them, so when an electric current passes through the liquid, it causes the crystals to align so that light can (or can’t) pass through. Think of each crystal as a shutter or gate, either allowing light to pass through or blocking it out. After passing through the frontmost polarized pane, the light then passes through a color filter that leaves it either red, green, or blue. Each cluster of red green and blue makes up one pixel on the screen. By selectively illuminating the colors within each pixel, a wide range of hues can be produced on the larger display.

Plasma displays work in an entirely different way. Instead of using a backlight and a set of filters to illuminate pixels on the screen, images on a plasma TVs are created by ionized gas (plasma) that lights up when you run an electrical current through it. The easiest way to undertand it is by thinking of each individual subpixel on the TV as a tiny neon light, or perhaps a miniature version of the florescent tubes you might be sitting under right now. The pixels that make up a plasma display are almost exactly the same technology, just on a much smaller scale.

For those of you who care to understand the science behind it all, here’s how the magic happens: An electrode applies an electrical current to a small cell filled with a noble gas mixture (usually neon and xenon). This excites the gas, ionizing it and transforming it into a plasma. This plasma emits ultraviolet light – which we can’t see – but when the UV light hits a phosphor coating that lines each cell, it causes the phosphor to glow and put out light that we can see. Depending on which particular phosphor the cell is coated with, it will create a red, green, or blue glow. Just like with LCD displays, each cluster of red green and blue subpixels makes up one pixel on the screen (see header image).

Due to the fact that plasma displays have the ability to completely turn off individual pixels, they boast far better black levels than LCD displays. Although LCD tech has improved over the years, the panels still aren’t that great at blocking out light completely, which makes it really hard for them to achieve true blackness on dark scenes. This is especially true of CCFL-backlit LCD screens. Some LED-backlit LCD TVs with local dimming can achieve black levels comparable to those of plasma TVs, but they’re generally much more expensive.

Because of the way they’re designed, plasma TV’s are also better at controlling the relative level of brightness of each red, blue, or green subpixel, so they typically produce greater contrast, more realistically textured images, and richer colors than their LCD counterparts.

Plasma displays also tend to have much better viewing angles than LCD TVs, mostly because the polarizing filters on LCD panels tend to cut out light that isn’t traveling straight forward. Since plasma displays don’t rely on filters to manage the light you see, their pictures can be enjoyed from a relatively wide angle without losing any integrity. Some higher end LCD TV’s incorporate technology to improve viewing angle, but most still aren’t on par with plasma displays.

When images move quickly across a screen, sometimes the pixels on an LCD panel can’t turn on and off fast enough, which results in what we call motion blur. Plasma screens generally don’t have this problem because the florescent phosphor coating in each subpixel stops glowing just a few nanoseconds after the electrode turns off, but LCD screens take a bit longer. This is because the crystals that control the flow of light (ie, shutters) take some extra time to open and close. That being said, however, many newer LCD screens feature refresh rates of 12oHz or faster, which effectively cuts out the problem of motion blur. Lower-end models might still have this drawback though, so be sure to check refresh rates before you buy anything.

If you’ve done even a small amount of research on plasma screens, there’s a good chance you’ve come across a thing called burn-in. This refers to an image that persists on the screen even after the image that created it is long gone – kinda like when somebody shines a flashlight in your face and you can still see streaks when you close your eyes. Burn-in works in the same way, but on your TV. If something bright stays on a plasma screen for too long (like CNN’s ticker or the Discovery Channel logo) it can sometimes leave a visible ghost behind after the image has gone away. This was a big problem in early plasma displays, but burn-in has largely been eradicated now that manufacturers have devised ways to cycle power to the phosphors and keep them from staying lit for too long. Still, it’s probably not a good idea to leave a static image on your screen for days on end.

Plasma TV’s are much more power-hungry than their LCD counterparts. Generally speaking, a CCFL-backlit LCD screen consumes about half the power of a plasma screen of the same size, and a LED-backlit LCD screen uses even less power than that. Depending on the cost of electricity where you live, you might want to factor in power costs if you’re thinking about buying a plasma TV.

Despite all the advances plasma technology has seen over the years, it still can’t match the brightness enjoyed by LED or CCFL-backlit LCD screens. This makes LCD TVs a better option for rooms with lots of light – especially since plasma TVs almost always have glossy, reflective screens.

So which type of TV should you go with? It depends on a few different factors, but if you’re looking for the best picture at the lowest price, definitely go with a plasma TV. Plasma sets cost roughly as much as your typical CCFL-backlit LCD TV, but offer a picture that’s on par with or better than some of the best, most expensive LED TV’s on the market.

However, if your home theater setup is in a room that’s got a lot of windows and ambient light pouring in, or you just have to have the thinnest TV on your block, you might want to opt for an LCD TV. So long as it’s within your budget, we recommend buying an LED-backlit or edgelit LCD TV – they’re thinner, prettier, and more energy-efficient than their CCFL cousins, but also more expensive. CCFL-backlit LCD TVs should only be a last resort – avoid them if at all possible.

A plasma display panel (PDP) is a type of flat panel display that uses small cells containing plasma: ionized gas that responds to electric fields. Plasma televisions were the first large (over 32 inches diagonal) flat panel displays to be released to the public.

Until about 2007, plasma displays were commonly used in large televisions (30 inches (76 cm) and larger). By 2013, they had lost nearly all market share due to competition from low-cost LCDs and more expensive but high-contrast OLED flat-panel displays. Manufacturing of plasma displays for the United States retail market ended in 2014,

Plasma displays are bright (1,000 lux or higher for the display module), have a wide color gamut, and can be produced in fairly large sizes—up to 3.8 metres (150 in) diagonally. They had a very low luminance "dark-room" black level compared with the lighter grey of the unilluminated parts of an LCD screen. (As plasma panels are locally lit and do not require a back light, blacks are blacker on plasma and grayer on LCD"s.)LED-backlit LCD televisions have been developed to reduce this distinction. The display panel itself is about 6 cm (2.4 in) thick, generally allowing the device"s total thickness (including electronics) to be less than 10 cm (3.9 in). Power consumption varies greatly with picture content, with bright scenes drawing significantly more power than darker ones – this is also true for CRTs as well as modern LCDs where LED backlight brightness is adjusted dynamically. The plasma that illuminates the screen can reach a temperature of at least 1,200 °C (2,190 °F). Typical power consumption is 400 watts for a 127 cm (50 in) screen. Most screens are set to "vivid" mode by default in the factory (which maximizes the brightness and raises the contrast so the image on the screen looks good under the extremely bright lights that are common in big box stores), which draws at least twice the power (around 500–700 watts) of a "home" setting of less extreme brightness.

Plasma screens are made out of glass, which may result in glare on the screen from nearby light sources. Plasma display panels cannot be economically manufactured in screen sizes smaller than 82 centimetres (32 in).enhanced-definition televisions (EDTV) this small, even fewer have made 32 inch plasma HDTVs. With the trend toward large-screen television technology, the 32 inch screen size is rapidly disappearing. Though considered bulky and thick compared with their LCD counterparts, some sets such as Panasonic"s Z1 and Samsung"s B860 series are as slim as 2.5 cm (1 in) thick making them comparable to LCDs in this respect.

Wider viewing angles than those of LCD; images do not suffer from degradation at less than straight ahead angles like LCDs. LCDs using IPS technology have the widest angles, but they do not equal the range of plasma primarily due to "IPS glow", a generally whitish haze that appears due to the nature of the IPS pixel design.

Superior uniformity. LCD panel backlights nearly always produce uneven brightness levels, although this is not always noticeable. High-end computer monitors have technologies to try to compensate for the uniformity problem.

Earlier generation displays were more susceptible to screen burn-in and image retention. Recent models have a pixel orbiter that moves the entire picture slower than is noticeable to the human eye, which reduces the effect of burn-in but does not prevent it.

Due to the bistable nature of the color and intensity generating method, some people will notice that plasma displays have a shimmering or fli