led vs lcd monitors free sample

Summary: Difference Between LCD and LED is that LCD monitor is a desktop monitor that uses a liquid crystal display to produce images. These monitors produce sharp, flicker-free images.

LCD monitor is a desktop monitor that uses a liquid crystal display to produce images. These monitors produce sharp, flicker-free images. LCD monitors have a small footprint; that is, they do not take up much desk space. LCD monitors are available in a variety of sizes, with the more common being 19, 20, 22, 24, 26, 27, and 30 inches — some are 45 or 65 inches. Most are widescreen, which are wider than they are tall. You measure a monitor the same way you measure a television, that is, diagonally from one corner to the other.

Mobile computers and mobile devices often have built-in LCD screens. Many are widescreen; some are touch screen. Notebook computer screens are available in a variety of sizes, with the more common being 14.1, 15.4, 17, and 20.1 inches. Netbook screens typically range in size from 8.9 inches to 12.1 inches, and Tablet PC screens range from 8.4 inches to 14.1 inches. Portable media players usually have screen sizes from 1.5 inches to 3.5 inches. On smart phones, screen sizes range from 2.5 inches to 4.1 inches. Digital camera screen sizes usually range from 2.5 inches to 4 inches. Read Innovative Computing 5-1 to find out about another use of LCD screens.

A liquid crystal display (LCD) uses a liquid compound to present information on a display device. Computer LCDs typically contain fluorescent tubes that emit light waves toward the liquid-crystal cells, which are sandwiched between two sheets of material. The quality of an LCD monitor or LCD screen depends primarily on its resolution, response time, brightness, dot pitch, and contrast ratio

Resolution is the number of horizontal and vertical pixels in a display device. For example, a monitor that has a 1440 3 900 resolution displays up to 1440 pixels per horizontal row and 900 pixels per vertical row, for a total of 1,296,000 pixels to create a screen image. A higher resolution uses a greater number of pixels and thus provides a smoother, sharper, and clearer image. As the resolution increases, however, some items on the screen appear smaller. With LCD monitors and screens, resolution generally is proportional to the size of the device. That is, the resolution increases for larger monitors and screens. For example, a widescreen 19-inch LCD monitor typically has a resolution of 1440 3 900, while a widescreen 22-inch LCD monitor has a resolution of 1680 3 1050. LCDs are geared for a specific resolution

Response time of an LCD monitor or screen is the time in milliseconds (ms) that it takes to turn a pixel on or off. LCD monitors’ and screens’ response times range from 3 to 16 ms. The lower the number, the faster the response time.

Brightness of an LCD monitor or LCD screen is measured in nits. A nit is a unit of visible light intensity. The higher the nits, the brighter the images.

Dot pitch,sometimes calledpixel pitch, is the distance in millimeters between pixels on a display device. Average dot pitch on LCD monitors and screens should be .30 mm or lower. The lower the number, the sharper the image.

Contrast ratio describes the difference in light intensity between the brightest white and darkest black that can be displayed on an LCD monitor. Contrast ratios today range from 500:1 to 2000:1. Higher contrast ratios represent colors better.

Shopping for a new TV is like wading through a never-ending pool of tech jargon, display terminology, and head-spinning acronyms. It was one thing when 4K resolution landed in the homes of consumers, with TV brands touting the new UHD viewing spec as a major marketing grab. But over the last several years, the plot has only continued to thicken when it comes to three- and four-letter acronyms with the introduction of state-of-the-art lighting and screen technology. But between OLEDs, QLEDs, mini-LEDs, and now QD-OLEDs, there’s one battle of words that rests at the core of TV vocabulary: LED versus LCD.

Despite having a different acronym, LED TV is just a specific type of LCD TV, which uses a liquid crystal display (LCD) panel to control where light is displayed on your screen. These panels are typically composed of two sheets of polarizing material with a liquid crystal solution between them. 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 it as a shutter, either allowing light to pass through or blocking it out.

Since both LED and LCD TVs are based around LCD technology, the question remains: what is the difference? Actually, it’s about what the difference was. Older LCD TVs used cold cathode fluorescent lamps (CCFLs) to provide lighting, whereas LED LCD TVs used an array of smaller, more efficient light-emitting diodes (LEDs) to illuminate the screen.

Since the technology is better, all LCD TVs now use LED lights and are colloquially considered LED TVs. For those interested, we’ll go deeper into backlighting below, or you can move onto the Local Dimming section.

Three basic illumination forms have been used in LCD TVs: CCFL backlighting, full-array LED backlighting, and LED edge lighting. Each of these illumination technologies is different from one another in important ways. Let’s dig into each.

CCFL backlighting is an older, now-abandoned form of display technology in which a series of cold cathode lamps sit across the inside of the TV behind the LCD. The lights illuminate the crystals fairly evenly, which means all regions of the picture will have similar brightness levels. This affects some aspects of picture quality, which we discuss in more detail below. Since CCFLs are larger than LED arrays, CCFL-based LCD TVs are thicker than LED-backlit LCD TVs.

Full-array backlighting swaps the outdated CCFLs for an array of LEDs spanning the back of the screen, comprising zones of LEDs that can be lit or dimmed in a process called local dimming. TVs using full-array LED backlighting to make up a healthy chunk of the high-end LED TV market, and with good reason — with more precise and even illumination, they can create better picture quality than CCFL LCD TVs were ever able to achieve, with better energy efficiency to boot.

Another form of LCD screen illumination is LED edge lighting. As the name implies, edge-lit TVs have LEDs along the edges of a screen. There are a few different configurations, including LEDs along just the bottom, LEDs on the top and bottom, LEDs left and right, and LEDs along all four edges. These different configurations result in picture quality differences, but the overall brightness capabilities still exceed what CCFL LCD TVs could achieve. While there are some drawbacks to edge lighting compared to full-array or direct backlight displays, the upshot is edge lighting that allows manufacturers to make thinner TVs that cost less to manufacture.

To better close the local-dimming quality gap between edge-lit TVs and full-array back-lit TVs, manufacturers like Sony and Samsung developed their own advanced edge lighting forms. Sony’s technology is known as “Slim Backlight Master Drive,” while Samsung has “Infinite Array” employed in its line of QLED TVs. These keep the slim form factor achievable through edge-lit design and local dimming quality more on par with full-array backlighting.

Local dimming is a feature of LED LCD TVs wherein the LED light source behind the LCD is dimmed and illuminated to match what the picture demands. LCDs can’t completely prevent light from passing through, even during dark scenes, so dimming the light source itself aids in creating deeper blacks and more impressive contrast in the picture. This is accomplished by selectively dimming the LEDs when that particular part of the picture — or region — is intended to be dark.

Local dimming helps LED/LCD TVs more closely match the quality of modern OLED displays, which feature better contrast levels by their nature — something CCFL LCD TVs couldn’t do. The quality of local dimming varies depending on which type of backlighting your LCD uses, how many individual zones of backlighting are employed, and the quality of the processing. Here’s an overview of how effective local dimming is on each type of LCD TV.

TVs with full-array backlighting have the most accurate local dimming and therefore tend to offer the best contrast. Since an array of LEDs spans the entire back of the LCD screen, regions can generally be dimmed with more finesse than on edge-lit TVs, and brightness tends to be uniform across the entire screen. Hisense’s impressive U7G TVs are great examples of relatively affordable models that use multiple-zone, full-array backlighting with local dimming.

“Direct local dimming” is essentially the same thing as full-array dimming, just with fewer LEDs spread further apart in the array. However, it’s worth noting that many manufacturers do not differentiate “direct local dimming” from full-array dimming as two separate forms of local dimming. We still feel it’s important to note the difference, as fewer, further-spaced LEDs will not have the same accuracy and consistency as full-array displays.

Because edge lighting employs LEDs positioned on the edge or edges of the screen to project light across the back of the LCD screen, as opposed to coming from directly behind it, it can result in very subtle blocks or bands of lighter pixels within or around areas that should be dark. The local dimming of edge-lit TVs can sometimes result in some murkiness in dark areas compared with full-array LED TVs. It should also be noted that not all LED edge-lit TVs offer local dimming, which is why it is not uncommon to see glowing strips of light at the edges of a TV and less brightness toward the center of the screen.

Since CCFL backlit TVs do not use LEDs, models with this lighting style do not have dimming abilities. Instead, the LCD panel of CCFL LCDs is constantly and evenly illuminated, making a noticeable difference in picture quality compared to LED LCDs. This is especially noticeable in scenes with high contrast, as the dark portions of the picture may appear too bright or washed out. When watching in a well-lit room, it’s easier to ignore or miss the difference, but in a dark room, it will be, well, glaring.

As if it wasn’t already confusing enough, once you begin exploring the world of modern display technology, new acronyms crop up. The two you’ll most commonly find are OLED and QLED.

An OLED display uses a panel of pixel-sized organic compounds that respond to electricity. Since each tiny pixel (millions of which are present in modern displays) can be turned on or off individually, OLED displays are called “emissive” displays (meaning they require no backlight). They offer incredibly deep contrast ratios and better per-pixel accuracy than any other display type on the market.

Because they don’t require a separate light source, OLED displays are also amazingly thin — often just a few millimeters. OLED panels are often found on high-end TVs in place of LED/LCD technology, but that doesn’t mean that LED/LCDs aren’t without their own premium technology.

QLED is a premium tier of LED/LCD TVs from Samsung. Unlike OLED displays, QLED is not a so-called emissive display technology (lights still illuminate QLED pixels from behind). However, QLED TVs feature an updated illumination technology over regular LED LCDs in the form of Quantum Dot material (hence the “Q” in QLED), which raises overall efficiency and brightness. This translates to better, brighter grayscale and color and enhances HDR (High Dynamic Range) abilities.

And now to make things extra confusing, part of Samsung’s 2022 TV lineup is being billed as traditional OLEDs, although a deeper dive will reveal this is actually the company’s first foray into a new panel technology altogether called QD-OLED.

For a further description of QLED and its features, read our list of the best TVs you can buy. The article further compares the qualities of both QLED and OLED TV; however, we also recommend checking outfor a side-by-side look at these two top-notch technologies.

There are more even displays to become familiar with, too, including microLED and Mini-LED, which are lining up to be the latest head-to-head TV technologies. Consider checking out how the two features compare to current tech leaders in

In the world of TV technology, there’s never a dull moment. However, with this detailed research, we hope you feel empowered to make an informed shopping decision and keep your Best Buy salesperson on his or her toes.

Did you know that, according to a recent study by Global, 85% of brands and agencies plan to increase their advertising investment? This figure illustrates the importance of this aspect in any marketing strategy. And although the Internet is usually the star medium, indoor and outdoor advertising is also gaining ground in shopping malls and big cities. Are you thinking of boosting your sales with this option? If so, and although we have already explained how LED technology works, it is important to also know what the advantages of LED are over LCD displays, two technologies that, at first sight, can be quite similar.

Before explaining the advantages of LED over LCD displays, we should highlight that the demand for this type of product for shop windows is booming for several reasons. One of them is that LED screens fulfil their function much better than their predecessors, LCD screens, because of the excellent image quality they provide and their ability to attract the attention of passers-by on the public highway.

But what is the difference between the two technologies? First of all, the technology of any LED TV is similar to that of the LCD screen, since, technically, they are also an LCD (these are the acronyms of the concept ‘liquid crystal screen’). However, there is a fundamental difference between the two: the generation of light. In the case of LCDs, the light is provided by neon tubes, whereas it is LED bulbs (light-emitting diodes) perform this function in LED displays.

On the other hand, the number of diodes on LEDs are than the number of neon tubes on LCD screens, which means that the lighting is higher quality. In addition, this makes LED displays thinner. The color contrast is also higher, providing a sharper and higher quality image.

Another advantage of LED displays over LCDs is that they will save electricity for your company. For example, the power consumption of the LED display can reduce the power consumption by up to 50% in comparison to similar LCD TV with the same operating hours and.

Another benefit of LED has to do with the conservation of the planet. The reason is that LED, being a mercury-free technology – unlike other monitors – is more environmentally friendly and sustainable. It is also better for people’s health, as exposure to mercury, even in very small quantities, can cause serious problems and harm fetuses when it comes to pregnant women. Mercury is equally toxic to the digestive system, the nervous and immune systems, the skin, the eyes, the lungs, and the kidneys.

Want more advantages of LED over LCD? Here’s another one that will help improve your business numbers: while the life of an LCD is usually no more than 60,000 hours, until its light source burns out, LED displays can run for between 60,000 and 100,000 hours. However, it’s not just about quantity, but also quality: while LED TVs are equipped with technology that always provides an optimal color palette, even when the color starts to fade, the LCD starts to show more and more black dots in the picture, due to continuous use (and corresponding to neon tubes that have stopped working).

And since we are talking about image quality, we should also refer to the behavior of the liquid crystal displays – both LEDs and LCDs – when they are directly affected by sunlight. For example, when we are in front of LED screens in shop windows or giant LED displays that emit during daylight hours (video scoreboards in stadiums would be a case in point). In this context, only LED technology can guarantee optimal viewing conditions at any time of day.

In relation to outdoor displays, we should also bear in mind that they require special protection, both against rain and vandalism. When this happens, only professional LED displays can offer this advantage.

Now that you are clear about the advantages of LED displays over LCD, you are probably considering purchasing an LED monitor for your business. This is where we get to the million-dollar question: how much does an LED display cost? The question is not simple, since the final bill will depend on several factors, such as its equipment or its dimensions. In Visual Led, in addition, we design LED screens to fit your needs and investment capacity.

Do you want to know how much an LED display would cost you? If so, we encourage you to calculate the price of an LED display online. You only have to introduce the requested variables, and you will instantly receive an estimated budget without any commitment of purchase on your part.

Of course, we must not lose sight of the fact that the marketing of outdoor LED displays is relatively recent and is part of a marking regulated by the laws of each country. Therefore, in some territories, certain formats must be adapted to the current legislation.

Most modern computer monitors, and even televisions, have an edge-lit LCD display that’s fundamentally similar to the first such displays sold decades ago, but that’s not where the future is headed. The twin threats of Mini-LED and OLED want to conquer the world of PC displays for themselves.

Modern OLED displays rarely exceed 1,000 nits of brightness, and when they do, are incapable of sustaining it. LG’s C9 OLED television, for example, can’t sustain a peak brightness above 160 nits (according to testing by Rtings). Mini-LED displays like Apple’s Liquid Retina XDR, Samsung’s Odyssey Neo G9, and Samsung’s QN90A television can hit peak brightness well above 1,000 nits and sustain at least 600 nits.

Wyatt points to this as a key advantage. The best HDR standards call for up to 10,000 nits of brightness. Current consumer Mini-LED displays don’t achieve this, but it’s possible future displays will.

And Micro-LED, which uses individual LEDs as per-pixel lighting elements, can reach even greater heights. Wyatt says his company’s VividColor NanoBright technology will be capable of reaching up to one million nits.

Such brightness is not necessary for computer monitors or home televisions and instead targets demanding niche components, such as avionics displays. Still, it hints that we’ve only seen a sliver of HDR’s real potential – and that Mini-LED and Micro-LED, not OLED, will lead the charge.

OLED’s greatest strength is the opposite of Mini-LED’s incredible brightness. The self-emissive nature of OLED means each pixel can be turned on or off individually, providing a deep, inky, perfect black level.

“Mini-LED has clear advantages in sources of supply and brightness,” Young said in an email, “but OLEDs have advantages in regards to contrast, particularly off-axis contrast, response times, and no halo effect.” The “halo effect,” also known as blooming, is the halo of luminance that often surrounds bright objects on a Mini-LED display.

The advantages of OLED add up to superior contrast and depth. You’ve likely noticed this when viewing an OLED television at your local retailer. High-quality content has an almost three-dimensional look, as if the display is not a flat panel but a window into another world.

Modern Mini-LED displays often claim to rival OLED. Apple’s Liquid Retina Display XDR, for example, lists a maximum contrast ratio of 1,000,000:1. In reality, Mini-LED still noticeably lags the contrast performance of OLED because it can’t light pixels individually. This will remain true at least until Micro-LED, which can light pixels individually, goes mainstream.

Mini-LED improves on traditional edge-lit LCD displays by improving the backlight. The LCD panel itself, however, is much the same as before and retains some flaws common to the technology.

Display quality can shift significantly depending on viewing angle, and significant blur will be visible when displaying fast motion. Both problems are inherent to LCD technology. The liquid crystals do not block light uniformly, so the image looks different from different angles, and require a few milliseconds to respond to a charge, causing blur or ghosting in rapidly changing images.

OLED is different from LCD technology. There’s no liquid crystals to twist or move. Each pixel is an organic element that creates its own light when a charge is applied. The light is emitted in a relatively uniform pattern and can turn on or off extremely quickly, removing the viewing angle and motion performance issues of LCD entirely.

The last few points—contrast, black levels, viewing angles, and response times—highlight the strengths of OLED technology. But, OLED has a weakness: durability.

Wyatt hammered this point during our conversation. The “O” in OLED stands for organic, and organic material will wear out. Indeed, exposure to light itself (and blue light in particular) wears down OLED, reducing the light produced by pixels over time.

This problem is most often discussed in the context of burn-in or image retention. Burn-in happens when specific pixels on an OLED panel degrade differently from those around them, creating a persistent shadow in the image.

OLED manufacturers downplay this issue. LG said in 2016 that its OLED televisions can endure 100,000 hours before they degrade to half their original maximum brightness. The company’s current OLED reliability page says that “reasonable, responsible usage” should not result in burn-in.

Want to see the effects yourself? I recommend Rting’s burn-in testing page, which shows results over a period of eight years (though, unfortunately, Rtings has not updated its result since February of 2020). This testing shows OLED degradation is indeed a thing, though its severity depends on how you use your display.

You might decide the risk is worth the reward. But if you want a display that you’ll use all day, day after day, for a decade or more, OLED isn’t the best choice. The burn-in is real.

Monitor pricing remains a sore point for PC enthusiasts. As explained in my deep-dive on upcoming OLED monitors, pricing is tied to the efficiency of production.

“OLEDs are less costly than MiniLEDs in tablets and notebooks if comparing them to Apple’s iPad Pro and MacBook Pro,” says Young. “On the other hand, in monitors, OLEDs are more expensive than MiniLEDs, and are not as bright.”

This explanation is backed up by the hardware you can buy today. OLED panels are available at reasonable prices in notebooks like the Dell XPS 13 and Samsung Galaxy Book Pro. OLED panels for monitors, on the other hand, are so expensive most manufacturers don’t even bother. The LG UltraFine 32EP950, which briefly went on sale this summer, retailed for $3,999.99.

Mini-LED is also expensive, but more affordable than OLED. Asus’ 32-inch ROG Swift PG32UQX retails for as little as $2,899.99 and Samsung’s super-ultrawide Odyssey Neo G9 is $2,499.99.

This advantage will likely continue in the near future. OLED pricing is reliant on availability of OLED panels, which are not as widely produced as LCD panels. Companies looking to build Mini-LED displays can design the backlight somewhat independently of the LCD panel and choose panels as needed based on the panel’s capabilities and pricing.

Because of this, there’s more ways for manufacturers to deliver Mini-LED displays in notebooks and monitors, which may lead to a more aggressive reduction in price.

The current OLED vs. Mini-LED battle is give-and-take. Mini-LED wins in brightness, HDR, durability, and pricing (of full-sized monitors). OLED wins in contrast, black levels, viewing angles, and motion performance.

OLED’s big break may come with the introduction of new fabs. Young says they will “lower costs significantly for 10-inch to 32-inch panels, giving OLED fabs the same flexibility as G8.5 LCD fabs, meaning the ability to target multiple applications from a single fab.” The first of these new fabs should start producing panels by 2024.

Affordable OLED seems alluring, but Wyatt champions a different approach. He believes the Micro-LED technology championed by Pixel Display will meld the strengths of LCD and OLED while ditching the weaknesses of both.

However, Micro-LED is a technology more relevant to the latter half of this decade. The more immediate fight will see OLED attempt to improve brightness and durability while Mini-LED pursues increasingly sophisticated backlights to mimic the contrast of OLED.

Personally, I think Mini-LED shows more promise—when it comes to PC displays, at least. The static images, long hours, and sustained brightness of Mini-LED displays pinches on OLED pain points, which will remain even if pricing becomes more affordable.

A Liquid Crystal Display (LCD) is one of the most enduring and fundamental technologies found in monitors, televisions, tablets, and smartphones. TVs and monitors once used cathode ray tubes (CRTs) to provide the image on your screen. But CRTs were bulky and contained dangerous chemicals. Once LCDs became affordable, they replaced CRTs.

An LCD features a panel of liquid crystal molecules. The molecules can be induced using an electrical current to take certain patterns which either block or allow light to pass through. An LCD TV or monitor has a light source at the rear of the display, which lights up the crystals. LCDs commonly use Cold Cathode Fluorescent Lamps (CCFL) to provide the TV or monitor backlight.

To provide a color image on your screen, the LCD has red, green, and blue sub-pixels in each screen pixel. Transistors within the display control the direction of light each pixel emits, which then passes through either a red, green, or blue filter.

Light Emitting Diodes (LEDs) are small semiconductors that emit visible light when an electrical current passes through them. LEDs are typically more efficient and longer-lasting than traditional lighting.

While manufacturers often use "LED" in place of "LCD," an LED TV is also a type of LCD. Instead of CCFL tubes to provide the LCDs backlight, rows of LEDs provide the backlight. The LEDs give better control of the light, as well as greater efficiency as it is possible to control individual LEDs.

For accuracy, a TV or monitor description should read "LED-Backlit LCD Monitor." But that is a) a mouthful and b) doesn"t allow for the creation of a separate marketable product. That"s not to say there aren"t differences between the two.

However, both LED and LCD monitors have different technologies that make certain panels more appealing to gamers, film buffs, designers, and so on. You should also note that on older screens, the difference between an LCD and LED TV or monitor is more pronounced, due to the relative age of the two lighting options.

There are several different types of LED and LCD monitors. When you"re trying to buy a new TV or monitor, understanding the differences and the terminology will help you bag a better deal. Here are some of the most common variations of the LED and LCD panels.

An Edge-Lit LED TV or monitor has its LEDs arranged around the rim of the display, behind the LCD panels facing the screen. The Edge-Lit option allows for slimmer designs, uses fewer LEDs, and can bring the cost of a new screen down. Light reflects across the screen uniformly to create the image.

One downside to an Edge-Lit screen is the dark contrast. Because the Edge-Lit LED display is brightest closer to the edges, color uniformity and black levels can become an issue, with some areas appearing darker than others.

A Full-Array LED display uses a grid of LED lights behind the LCD. The LEDs shine outwards directly towards the LCD, creating a bright and uniform picture. Full-Array LED panels enjoy the efficiency benefits of LEDs.

For the best image reproduction, a Full-Array LED display may include local dimming. Local dimming means that groups of LEDs can switch on and off as required to provide better overall control of the brightness level.

LEDs are often referred to as emitting white light. Actually, LEDs produce light closer to yellow than a pure white. That difference can create a color shift in the image you see on your screen. To improve on this issue, some manufacturers replace white LEDs with groupings of red, green, and blue (RGB) LEDs.

The display uses advanced electronics and programming to control the RGB LEDs accurately, along with more LEDs. The combination increases the cost of an RGB LED screen significantly for what most viewers would consider a marginal improvement. RGB LED displays never became mainstream because of their higher cost.

Organic Light-Emitting Diodes (OLED) are an advanced form of LED lighting found in some LED monitors. Each pixel of an OLED TV can glow or dim independently, resulting in much better black levels, extremely sharp colors, and better contrast ratios. The majority of OLED TVs and monitors have excellent viewing angles and color quality.

Without a doubt, OLED TVs and monitors (and even smartphone screens) have incredible color depth. But that does come at a cost. The latest generation of flagship smartphones all feature OLED screens, and it is a contributing factor to their massive cost. Another consideration is power. An OLED screen consumes more power than other LED-backlit screens and standard LCD screens.

The acronyms continue with QLED, which stands for Quantum Dot LED. Samsung"s QLED improves color accuracy as much as 90-percent from a regular LED TV or monitor and can hit the high levels of brightness and color depth that HDR requires.

So, what is a quantum dot monitor? In short, quantum dots are semiconductor nanocrystals that absorb light at one wavelength and output it at a different wavelength. The LEDs in a QLED emit all of the blue shades the picture requires. But a blue picture isn"t what consumers want. The quantum dots refract the blue LED light into the green and red shades needed to complete the picture.

A single quantum dot monitor or TV contains billions of semiconductor nanocrystals. Those nanocrystals give QLED screens outstanding black range and color depth, as well as excellent color saturation and contrast.

Just as there are types of LED monitor technology, so is there LCD monitor and TV technology, too. The type of LCD tech powering your screen makes a difference to the final picture. Here"s what you need to look out for.

Twisted nematic (TN) was one of the first LCD panel types, dating back to the 1980s. TN panels have fast response time. Most of the fastest gaming monitors use a TN LCD panel to offer exceptionally fast refresh rates, up to 240Hz. That level of refresh isn"t necessary for most people, but it can make a difference for top-level gamers (for instance, in reducing motion blur and image transition smoothness).

While a VA LCD panel has a better color range than a TN panel, they also have a slower refresh rate. They also usually cost more and, as such, are rarely marketed toward gamers. Between TN panels and IPS panels (read below), VA is the least popular LCD panel technology.

In-Plane Switching (IPS) panels are considered the best LCD panel technology for a variety of reasons. An IPS panel offers very wide viewing angles with very fast refresh rates. They"re not as fast as a TN panel, but IPS panels are widely available at 144Hz. At the time of writing, the first few 240Hz IPS LCD panels are hitting the market, although they are extremely expensive for a marginal gain.

Color-wise, IPS panels are excellent. High-quality IPS LCD panel prices continue to fall. However, there are several reasons why you shouldn"t buy a ridiculously cheap IPS gaming monitor.

The type of LCD panel you need depends on its use. Gamers want fast response times and rich depth of color, which is why IPS panels are a great option. If you"re more concerned about picture quality for your favorite films, an OLED panel will perform extremely well.

Still, now you know the terminology behind LCD panels and the pros and cons to each type, you can make an informed decision for your TV or monitor upgrade. But wait, the type of LCD or LED panel isn"t the only thing to consider. Take a moment to learn about the differences between 4K, Ultra HD, and 8K screens.

Sometimes the distance between good and great seems like hardly any distance at all — such as liquid crystal displays (LCDs) versus light-emitting diode (LED) displays. Both are suitable for retail window signage, campus wayfinding or large video walls. But LCD and LED have significant differences, and their specific benefits are worth understanding so you can choose the best displays for your business needs.

LCD is the broader category; LED is a subset. In other words, all LED displays are LCDs, but not all LCDs are LED. LCDs are made up of hundreds of thousands — even millions — of individual pixels built from liquid crystals. Each pixel is capable of displaying a color when it receives an electrical charge. Like a mosaic, the displayed image is built from tiny elements that combine to form the overall picture.

But the liquid crystals don’t produce any light of their own, so in order for the image to be illuminated, the liquid crystals need to be backlit. LCDs are illuminated by cold cathode fluorescent lamps (CCFLs), evenly positioned behind the pixels so that, at least in theory, every part of the screen is evenly lit and at consistent brightness.

Up to a point, LED displays are much the same. An LED screen also uses liquid crystals to generate color — or pure black (no color), by not charging a specific pixel. So LED displays have the same need for backlighting. But rather than CCFL, tiny individual lights (light-emitting diodes) illuminate the liquid crystals.

The individual LEDs can be arranged one of two ways: full-array or edge-lit. For edge lighting, the LEDs are arranged around the edges of the back of the screen. Full-array, on the other hand, calls for many LEDs to be lined up evenly across the back of the screen, where they can be arranged into zones (usually called “dimming zones” or “local dimming”).

Is LED just plain better than LCD? Well, for a while, LCD screens represented the cutting edge of digital signage. But now, about the only meaningful advantage of LCD over LED is price point. As LCD is becoming outdated, it tends to be less of an upfront investment. In every other respect, though, LED displays have the advantage.

No matter the arrangement of the backlighting, LED has a greater nit value than LCD, which means it’s brighter (“nit” comes from the Latin “nitere,” meaning “to shine”). The average nit value for LCDs is between 500 and 700 nits, while LEDs are typically between 1,200 and 2,400 nits. With greater brightness comes greater contrast, and all-day visibility on outdoor displays.

Despite the energy output, higher brightness doesn’t necessarily mean a shorter lifespan. In fact, LED displays have an average lifespan of 10 years — double the average five-year lifespan of LCDs. Factoring longevity into the cost of your signage, LED’s longer lifespan can make it cheaper than LCD in the long run.

Even with edge lighting, LED produces more vividly lifelike images than CCFL-backlit LCDs — and with sleeker hardware, thanks to their minimalist design. And while LCD bezels have drastically reduced over time, they’re still greater than zero. LED has no bezels at all.

Full-array backlighting requires a little more depth to the screen, but with discrete dimming zones, LEDs can be illuminated far more precisely — which, in turn, means more accurate and engaging visuals.

LED isn’t the first technology to realize miniaturization is the way forward. Even as screens get bigger, the next big step is made of smaller parts: microLEDs.

Up to 40 times smaller than regular LEDs, microLEDs allow backlighting to be even more precisely targeted, with many times more diodes. This, in turn, delivers a more accurate picture, with greater contrast and highly focused areas of brightness. Samsung’s The Wall is a spectacular example of what microLED is capable of.

Whether you need your digital signage to entertain, inform or simply impress, understanding the differences between LCD and LED will allow you to make a better-informed decision.

With best-in-class picture quality and exceptional durability,Samsung LED displayscan help your business deliver content that engages, informs and entertains.Samsung’s trade-in program makes it easy for businesses to upgrade their video wall with LED technology. Once you’ve chosen your displays, learn how you can configure and tailor their real-time messaging using an integrated CMSin this free guide.

Before buying a new TV, you should know the difference between LED and LCD displays. Both provide a high-definition picture, but each handles creating it a little differently and has a few other differences as well. We examined these two screen technologies to help you get a better idea of which one is right for you.

Both LCD and LED TV screens and monitors display a bright, high-definition picture. If you want to save money on the hardware, go with the older LCD setup. LED screens may offer more cost savings over time, however, because the system generally requires less energy to operate.

Although more expensive, newer LED screens are generally lighter than LCDs, especially on an edge-lit display that has fewer components to add bulk to the device.

Before you buy an LCD TV with LED backlighting, consider one important factor: price. LED full-array backlit TVs are impressive but are more expensive than their florescent-lit peers. If picture quality is important to you, spending more money to enjoy the benefits of full-array LED backlighting may make sense for you. If you want the thinnest TV on the block, edge-lit LED is the way to go.

If you"re a bargain shopper, you will probably satisfy yourself and your wallet with a florescent-lit LCD TV. That said, they are getting harder to find since demand is shrinking.

In the context of televisions, the term LED refers to the TV backlighting system, not the display technology that produces the image content. LED TVs use LCD displays; however, they use LED backlights rather than the fluorescent backlights found in traditional LCD TVs. Just as LED TVs are a type of LCD TV, OLED and S-AMOLED are different types of LED TVs.

The liquid crystals in LCD TVs do not produce light, so backlighting is needed to illuminate the image for the viewer. LCD sets originally used a series of fluorescent tubes (termed CCFL-backlit technology) for this purpose. In LED TVs, the illumination source is a series of light-emitting diodes, better known as LEDs. In most modern LCD sets, those fluorescent tubes have been replaced with full-array LEDs, but both types of TVs still use LCD technology.

Each backlighting system has advantages and disadvantages. Edge-lit sets are typically thinner and lighter than those that use a full array because the lighting source takes up less space. Full array sets are thicker and heavier, but they make up for that with local dimming, which means one section of the LED panel can be dimmed while other sections remain bright. This feature slightly improves image contrast.

LED sets that use full-array backlighting tend to produce the best picture of all LCD TVs. Those that use edge lighting sacrifice picture quality, but they are the lightest and thinnest TVs on the market.

Because LCD screens rely on fluorescent panels behind the entire screen to make the picture visible, they use more energy than LED sets. TVs and monitors that use edge-lighting are more efficient than full-array ones because they contain fewer lights in general. However, full-array screens don"t necessarily use all of the LED backlights at once.

When it comes to picture quality, LED TVs look better than older LCD TVs. Manufacturers also make a big deal out of LED backlighting because sets that use the technology are usually more energy-efficient than CCFL LCD TVs. Therefore, the money you save on your power bill could eventually offset the extra cost of an LED TV.

You"ll be happy with the picture regardless of what kind of display you buy. Still, LEDs have a few practical advantages that make them a better purchase than the older LCDs.

Wholesalers on Alibaba.com have a wide range of functions and such a curved monitorphone. LEDs are an excellent choice for smart watches as they are wireless and have a built-in Light-emitting Diode (LAG)) for the convenience of large-sized ones, LEDs are equipped with all the functions as a curved monitorphone, and it has a built-in media player and the possibility to see a difference in the second-hand TV of the choice. LED smart watches are wirelessly designed and allow the user to see the image in all, and they"re looking great for them.

With all the advantages and disadvantages, lcdds are essentially a good choice for those who see the TV starting from 4k smartphone. Nowadays, in addition to the wholesale models, lcdds are essentially a good option for those that don ’ t have the capacity of a device.

"Between 0.0001 and 0.00001 nits" "Sony claims an OLED contrast range of 1,000,000:1. When I asked how the contrast could be so high I was told that the surface is SO black the contrast is almost infinite. If the number representing the dark end of the contrast scale is nearly zero then dividing that number into the brightest value results in a very, very high contrast ratio."

Does not normally occur at 100% brightness level. At levels below 100% flicker often occurs with frequencies between 60 and 255 Hz, since often pulse-width modulation is used to dim OLED screens.

No native resolution. Currently, the only display technology capable of multi-syncing (displaying different resolutions and refresh rates without the need for scaling).Display lag is extremely low due to its nature, which does not have the ability to store image data before output, unlike LCDs, plasma displays and OLED displays.

The Hisense U8H matches the excellent brightness and color performance of much pricier LCD TVs, and its Google TV smart platform is a welcome addition. But it’s available in only three screen sizes.

The Hisense U8H is the best LCD/LED TV for most people because it delivers the performance of a much pricier TV yet starts at under $1,000, for the smallest (55-inch) screen size. This TV utilizes quantum dots, a full-array backlight with mini-LEDs, and a 120 Hz refresh rate to deliver a great-looking 4K HDR image. It’s compatible with every major HDR format. And it’s equipped with two full-bandwidth HDMI 2.1 inputs to support 4K 120 Hz gaming from the newest Xbox and PlayStation consoles. Add in the intuitive, fully featured Google TV smart-TV platform, and the U8H’s price-to-performance ratio is of inarguable value.

Chief among the U8H’s many strengths is its impressive peak brightness. When sending it HDR test patterns, I measured an average brightness of 1,500 nits, with peaks just north of 1,800 nits (a measurement of luminance; see TV features, defined for more info). To put that into perspective, consider that the 65-inch version of our budget 4K TV pick (the TCL 5-Series) typically costs around half as much as the 65-inch U8H but achieves only around 30% to 40% of its brightness. On the other side of the coin, the 65-inch version of our upgrade pick (the Samsung QN90B) costs almost twice as much as the 65-inch U8H, but it achieves only nominally higher brightness. Adequate light output creates convincing highlights and image contrast and (when necessary) combats ambient light from lamps or windows. It is a necessity for any TV worth buying—especially if you hope to watch HDR movies or play HDR games—and the U8H simply outpaces most TVs in its price range (and some in the next price bracket up, too).

Key to this functionality is the U8H’s employment of mini-LED backlighting with local dimming, which allows this TV to produce very bright light while still maintaining satisfyingly deep black levels that are typically free of blooming (or light bleed that’s visible around bright objects against a dark backdrop). This not only ensures impressive image contrast, it also makes the U8H a viable choice for most rooms, whether they’re brighter than average or dimmed down like a movie theater.

That’s not to say the U8H has pixel-precise light control—it’s not an OLED TV, after all—but it does a terrific job most of the time. In fact, in our tests, the U8H bested last year’s upgrade pick, the Samsung QN90A, in certain scenarios: The intro to Guillermo del Toro’s Cabinet of Curiosities on Netflix features the filmmaker against a pitch-black backdrop. Though last year’s QN90A failed to maintain perfect control over dimming elements during this scene (the black backdrop brightened distractingly once a sufficient amount of brighter content appeared on screen), the U8H did not. (For the record, the newer QN90B also passed this test.) The U8H’s mini-LEDs also help the screen look uniformly bright: Although the U8H is still not as good as an OLED TV in this respect, it shows very little indication of being a backlight-driven display, even during tricky scenes with large swaths of dim lighting.

The U8H’s brightness, black-level integrity, and local-dimming abilities make this an excellent TV for watching HDR content. The U8H is capable of playing HDR content in all of the major formats (HDR10, HDR10+, Dolby Vision, and HLG), but when it comes to impressive HDR, what’s under the hood is much more important than format compatibility. The most crucial thing for good HDR is high brightness and deep color saturation, and the U8H’s quantum dots achieve the latter. It’s not as simple as just having quantum dots, however: While many TVs (even the budget options) have quantum dots nowadays, what is often not taken into account is that brightness directly affects color saturation. For example, both the 2022 TCL 6-Series and the Hisense U8H are equipped with quantum dots, mini-LED backlights, and local dimming. But because the U8H is notably brighter than the 6-Series, it also achieves a higher total color volume. During our color-volume testing, the U8H exhibited color ranges at more than 100% of the DCI-P3 color space (the range of color needed to properly display HDR content), and it is capable of roughly 10% more total color volume compared with the 6-Series.

And thanks to Hisense’s inclusion of Filmmaker Mode, it’s easy to rein in the U8H’s brightness abilities for a more-subdued and filmic experience in a darker room. Our measurements revealed that this mode has a very accurate white balance, mostly accurate colors (green is a bit oversaturated, but not egregiously so), and a perfect “dark room” gamma (which controls how quickly the video signal transitions from dark to light). Additionally, the TV’s 120 Hz refresh rate means it can play Blu-ray discs at 24 fps without the judder that’s usually present on TVs with 60 Hz refresh rates.

The Hisense U8H has some difficulties with banding, or areas of uneven gradation, where transitions that should appear smooth instead look like “bands” of color (sometimes also called posterization). Like many current 4K HDR TVs, the U8H uses an 8-bit panel rather than a 10-bit panel, which affects the color decoding and color presentation process. This is usually relevant only with HDR video and games. When playing games on the PlayStation 5 and Xbox Series X, I saw a few instances where the content wasn’t rendered correctly and displayed ugly splotches of color on the screen. However, this almost always occurred during static screens (such as a pause menu or loading screen); I rarely spotted it during actual gameplay. Hisense has stated that it would address the problem in a future firmware update, but at the time of writing it was still present. This is a flaw that may give dedicated gamers pause, but we don’t consider it to be a dealbreaker for most people.

Finally, like most TVs that use vertical alignment (VA) LCD panels, the U8H has a limited horizontal viewing angle, which may be a bit annoying if you’re hoping to entertain a large crowd. Our upgrade pick uses a special wide-angle technology to address this.

For gaming, use the game picture mode (the TV should switch into this mode automatically when paired with the newer game consoles), and then go into the Gaming submenu to make sure the right settings (VRR) are enabled. We recommend leaving the HDMI setting in “auto,” unless you notice that your game console is incorrectly identified.