difference between super amoled and tft display factory

AMOLED and TFT are two types of display technology used in smartphones. AMOLED (active-matrix organic light-emitting diode) displays are made up of tiny organic light-emitting diodes, while TFT (Thin-Film Transistor) displays use inorganic thin-film transistors.

AMOLEDs are made from organic materials that emit light when an electric current is passed through them, while TFTs use a matrix of tiny transistors to control the flow of electricity to the display.

Both technologies have their own advantages and disadvantages. So, how do you know which one is best for your needs? We compare these two technologies below.

Refresh Rate: Another key difference between AMOLED and TFT displays is the refresh rate. The refresh rate is how often the image on the screen is updated. AMOLED screens have a higher refresh rate than TFT screens, which means that they can display images more quickly and smoothly.

Response Time: The response time is how long it takes for the pixels to change from one colour to another. AMOLED screens have a shorter response time than TFT screens..

Colour Accuracy/Display Quality: AMOLED screens are more accurate when it comes to displaying colours. This is because each pixel on an AMOLED screen emits its own light, which means that the colours are more pure and true to life. TFT screens, on the other hand, use a backlight to illuminate the pixels, which can cause the colours to appear washed out or less vibrant.

Viewing Angle: The viewing angle is the angle at which you can see the screen. AMOLED screens have a wider viewing angle than TFT screens, which means that you can see the screen from more angles without the colours looking distorted.

Power Consumption: One of the main advantages of AMOLED displays is that they consume less power than TFT displays. This is because the pixels on an AMOLED screen only light up when they need to, while the pixels on a TFT screen are always illuminated by the backlight.

Production Cost: AMOLED screens are more expensive to produce than TFT screens. This is because the manufacturing process for AMOLED screens is more complex, and the materials used are more expensive.

Availability: TFT screens are more widely available than AMOLED screens and have been around for longer. They are typically used in a variety of devices, ranging from phones to TVs.

Usage: AMOLED screens are typically used in devices where power consumption is a concern, such as phones and wearable devices. TFT screens are more commonly used in devices where image quality is a higher priority, such as TVs and monitors.

AMOLED and TFT are two different types of display technology. AMOLED displays are typically brighter and more vibrant, but they are more expensive to produce. TFT displays are cheaper to produce, but they are not as bright or power efficient as AMOLED displays.

The display technology that is best for you will depend on your needs and preferences. If you need a screen that is bright and vibrant, then an AMOLED display is a good choice. If you need a screen that is cheaper to produce, then a TFT display is a good choice. However, if you’re worried about image retention, then TFT may be a better option.

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Thanks for the display technology development, we have a lot of display choices for our smartphones, media players, TVs, laptops, tablets, digital cameras, and other such gadgets. The most display technologies we hear are LCD, TFT, OLED, LED, QLED, QNED, MicroLED, Mini LED etc. The following, we will focus on two of the most popular display technologies in the market: TFT Displays and Super AMOLED Displays.

TFT means Thin-Film Transistor. TFT is the variant of Liquid Crystal Displays (LCDs). There are several types of TFT displays: TN (Twisted Nematic) based TFT display, IPS (In-Plane Switching) displays. As the former can’t compete with Super AMOLED in display quality, we will mainly focus on using IPS TFT displays.

OLED means Organic Light-Emitting Diode. There are also several types of OLED, PMOLED (Passive Matrix Organic Light-Emitting Diode) and AMOLED (Active Matrix Organic Light-Emitting Diode). It is the same reason that PMOLED can’t compete with IPS TFT displays. We pick the best in OLED displays: Super AMOLED to compete with the LCD best: IPS TFT Display.

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Tried and trusted TFT technology works by controlling brightness in red, green and blue sub-pixels through transistors for each pixel on the screen. The pixels themselves do not produce light; instead, the screen uses a backlight for illumination.

By contrast the Active Matrix OLED (AMOLED) display requires no backlight and can light up or turn off each of their pixels independently. As the name suggests, they are made of organic material.

An AMOLED display has many other benefits which make it a superior looking display including exceptional vieiwng angles and a display that looks practically black when it is switched off.

So, why use a TFT display? Well, it is a mature technology meaning the manufacturing processes are efficient, yields high and cost much lower than AMOLED.

TFT displays also have a much longer lifespan than AMOLED displays and are available in a far greater range of standard sizes, which can be cut down to fit a space restricted enclosure for a relatively low cost adder.

Which type of display you choose really depends on your application, environment and users, so why not get in touch with us today to discuss your requirements.

AMOLED (Active Matrix Organic Light Emitting Diode) and TFT (Thin Film Transistor) are the two types of displays that are used in mobile phones. TFT is actually a process of producing the displays and is used even by AMOLED but for most purposes, TFT is used to refer to LCD displays. The difference between them is the material as AMOLED uses organicmaterials, mainly carbon, while TFT does not.

There are differences between the two that are quite tangible. For starters, AMOLED generates its own light rather than relying on a backlight like a TFT-LCD does. This consequently means that AMOLED displays are much thinner than LCD displays; due to the absence of a backlight. It also results in much better colors than a TFT is capable of producing. As each pixel’s color and light intensity can be regulated independently and no light seeps from adjacent pixels. A side by side comparison of the two displays with the same picture should confirm this. Another effect of the lack of a backlight is the much lower power consumption of the device. This is very desirable when it comes to mobile phones where every single feature competes for the limited capacity of the battery. As the screen is on 90% of the time that the device is being used, it is very good that AMOLED displays consume less. Just how much of a difference is not very fixed though as it really depends on the color and intensity of the image. Having a black background with white text consumes much less energy than having black text on a white background.

The biggest disadvantage that AMOLED has is the shorter lifespan of the screen compared to TFT. Each pixel in the display degrades with each second that it is lit and even more so the brighter it is.  Despite improvements on the lifetime of AMOLED displays, AMOLED still only lasts a fraction of the lifetime of a TFT display. With that said, an AMOLED display is able to outlast the usable lifetime of the device before parts of it start to degrade.

The main hindrance to the massive adaptation of AMOLED is the low production numbers. TFT has been in production for much longer and the infrastructure is already there to meet the demands.

This rise of small, powerful components has also led to significant developments in display technology. The most recent of which, AMOLED, is now the main competitor for the most common display used in quality portable electronics – the TFT–LCD IPS (In-Plane Switching) display. As more factories in the Far East begin to produce AMOLED technology, it seems likely we will enter a battle of TFT IPS versus AMOLED, or LCD vs LED. Where a large percentage of a product’s cost is the display technology it uses, which provides best value for money when you’re designing a new product?

TFT IPSdisplays improved on previous TFT LCD technology, developed to overcome limitations and improve contrast, viewing angles, sunlight readability and response times. Viewing angles were originally very limited – so in-plane switching panels were introduced to improve them.

Modern TFT screens can have custom backlights turned up to whatever brightness that their power limit allows, which means they have no maximum brightness limitation. TFT IPS panels also have the option for OCA bonding, which uses a special adhesive to bond a touchscreen or glass coverlens to the TFT. This improves sunlight readability by preventing light from bouncing around between the layers of the display, and also improves durability without adding excess bulk; some TFT IPS displays now only measure around 2 mm thick.

AMOLED technology is an upgrade to older OLED technology. It uses organic compounds that emit light when exposed to electricity. This means no backlight, which in turn means less power consumption and a reduction in size. AMOLED screens tend to be thinner than TFT equivalents, often produced to be as thin as 1 mm. AMOLED technology also offers greater viewing angles thanks to deeper blacks. Colours tend to be greater, but visibility in daylight is lower than IPS displays.

As manufacturers increasingly focus on smaller devices, such as portable smartphones and wearable technology, the thinness and high colour resolution of AMOLED screens have grown desirable. However, producing AMOLED displays is far more costly as fewer factories offer the technology at a consistent quality and minimum order quantities are high; what capacity there is is often taken up the mobile phone market Full HD TFT IPS displays have the advantage of being offered in industry standard sizes and at a far lower cost, as well as offering superior sunlight visibility.

The competition between displays has benefitted both technologies as it has resulted in improvements in both. For example, Super AMOLED, a marketing brand by Samsung, involves the integration of a touchscreen layer inside the screen, rather than overlaid on it. The backlight in TFT technology means they can never truly replicate the deep blacks in AMOLED, but improvements have been made in resolution to the point where manufacturers like Apple have been happy to use LCD screens in their smartphones, even as they compete with Samsung’s Super AMOLED.

Aside from smartphones, many technologies utilise displays to offer direct interaction with customers. To decide whether TFT LCD will survive the rise of AMOLED technology, we must first recap the advantages of LCD. The backlit quality means that whites are bright and contrast is good, but this will wear down a battery faster than AMOLED. Additionally, cost is a significant factor for LCD screens. They are cheaper, more freely available and are offered in industry standard sizes so can be ordered for new products without difficulty.

It seems hard to deny that AMOLED will someday become the standard for mobile phones, which demand great colour performance and are reliant on battery life. Where size is an issue, AMOLED will also grow to dominance thanks to its superior thinness. But for all other technologies, particularly in industrial applications, TFT-LCD offers bright, affordable display technology that is continually improving as the challenge from AMOLED rises.

Typically, when scrolling through web pages and specs sheets of many smartphones, users are often faced with a number of confusing terminologies, particularly in the display department. While many smartphone enthusiasts and experts are familiar with these smartphone display technologies, many newbies aren’t.

There are more than four display types used on smartphones, and these displays are relative to the quality of images, colour quality, battery life, and even the price of the device. We explain the tech behind each known display types on smartphones.

LCD is an acronym that stands for Liquid Crystal Display and it is one of the most commonly used display by OEMs on their devices. LCD displays are further categorised into two types on the basis of the technology used to make them. The two types are IPS LCD and TFT LCDs.

TFT stands Thin-film Transistor and de facto, it really isn’t a type of display. TFT is only the technology used to produce LCD display panels. TFT LCD displays use an ‘Active Matrix Technology” where the display transistor and capacitor have individual pixels attached to them. In fact, each pixel can have as many as four transistors; for switching them off and on easily. TFT displays are widely known for having high contrast ratios, resolution and image quality. They are also cheaper to produce but not as cheap as IPS LCD.

IPS stands for In-Plane Switching and it is the most popularly used type of LCD panels for a number of reasons. First, compared to TFT, the crystal/pixel orientation on IPS LCD is different. This modification allows for improved colour reproduction, better viewing angles, and reduced energy consumption. This is why IPS LCD is preferred over TFT by most gadgets manufacturers.

Generally, LCDs are known as the “backlit displays” because the pixels on the display are powered by a polarized light engineered to the screen. The light passes through the (horizontal and vertical) filters which help determine the pixel’s brightness. Although the inclusion of a backlight makes LCD displays (and phones) thicker, pixels are generally more closely packed, colours are more natural, and images — sharper.

OLED stands for “Organic light-emitting diode”. OLED is one of the latest display innovation used in many gadgets and electronics like smartphones and TVs. Unlike LCD displays, OLED panels produce their own light and do not rely on a backlight. This self-emission is achieved when an electrical current passes through two conductors with an organic carbon-based film between them.

For every pixel in an OLED panel, this light emission process takes place, except when black is being displayed; the pixels are turned off instead. This makes OLED the best display that shows true black colour. The process of turning off pixels when displaying black is also a battery-wise feature of OLED panels.

Regarding quality, OLED are generally better at displaying blacks. They are also slimmer, dissipate less heat, and possess better contrast ratio when compared to LCDs. However, they are more expensive to produce and in turn lead to an increase in the price of smartphones they are used on. Shorter lifespan is also a downside to OLED displays.

AMOLED is an advanced type of OLED display that uses an “Active Matrix” technology. AMOLED is the acronym for Active Matrix Organic Light Emitting Diode (AMOLED). Like OLED, AMOLED pixels also emit their own light and further uses an active matrix system attached to a thin-film transistor (TFT) to exert more control over each pixels. This results to better visual experience; darker blacks, deeper brights, and higher refresh rates.

AMOLED panels are mostly used in big-sized smartphones as it supports almost any display size. One downside to AMOLED panels, though, is poor usability under sunlight.

Also called S-AMOLED, Super AMOLED is an upgrade of AMOLED panels. Unlike regular AMOLED, this upgrade uses almost the same technology but with architectural modifications that makes it better. In S-AMOLED, the touch sensor component have been integrated with the screen; both are separated in regular AMOLED.

This difference results in brighter display, reduced power consumption, reduced sunlight reflection, enhanced outdoor readability, and wider viewing angles. Super AMOLED is one the best displays out there and can be found on many flagship devices like the Samsung Galaxy A7 (2018) with three rear cameras, Samsung Galaxy Note9.

You can easily identify your smartphone’s screen type through a simple Google search of your phone specifications. You should see your device’s screen type under the display department. The image below shows the screen type (IPS LCD) of the Coolpad Note 5.

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OLED displays have become increasingly common and accessible over the past few years. While they were once reserved for premium smartphones, you’ll now find OLED displays at every smartphone price point. Not every OLED display is equal, though – differences in materials and manufacturing processes can result in varying display qualities. In that vein, let’s explore the differences between POLED vs AMOLED, and what these acronyms mean in the real world.

Before differentiating between POLED and AMOLED, it’s worth understanding the fundamentals of OLED display technology. To that end, let’s ignore the P and AM prefixes for now.

If you look at an OLED display under a microscope, you’ll see these diodes arranged in various red, green, and blue configurations in order to produce a full range of colors. OLED has a key advantage over conventional LCDs – individual light emitters can be switched completely off. This gives OLED deep blacks and an excellent contrast ratio.

Naturally, light emitters in an OLED display need a power source in order to function. Manufacturers can use either a passive wiring matrix or an active wiring matrix. Passive matrix displays provide current to an entire row of LEDs, which isn’t ideal but it is cheap. An active matrix, on the other hand, introduces a capacitor and thin-film transistor (TFT) network that allows each pixel to be driven individually. This driving matrix is part of the panel that sits on top of a base substrate.

Today, virtually all high-resolution OLED displays use active-matrix technology. This is because a passive matrix requires higher voltages the more pixels you introduce. High voltage reduces LED lifetimes, making a passive matrix OLED impractical.

AMOLED simply refers to an Active Matrix OLED panel. The AMOLED branding has become synonymous with Samsung Display’s OLED panels over the years. However, all smartphone OLED panels, including those from Samsung’s rivals like LG Display use active-matrix technology too – they just aren’t marketed as such.

In case you’re wondering what Super AMOLED means, it’s another bit of branding to indicate the presence of an embedded touch-sensitive layer. Similarly, Dynamic AMOLED refers to a display with HDR capabilities, specifically support for Samsung’s favored HDR10+ standard.

Now that we know the layered structure of an OLED display, we can move on to the plastic part. While the first wave of OLED panels was built using glass substrates, the desire for more interesting form factors has seen manufacturers use more flexible plastic components. This is where the P in POLED comes from.

Glass is fixed and rigid, while plastic substrates can be more easily formed into new shapes. This property is absolutely essential for curved screens as well as foldable devices like Samsung’s Galaxy Fold series. Working with plastics is also much more cost-effective than glass.

Manufacturers have experimented with a range of plastics for flexible displays, including polyethylene terephthalate (PET) and polyethylene naphthalate (PEN). OLED manufacturers have settled on using polyimide plastics (PI) that can better withstand high TFT manufacturing temperatures. The type of substrate and heating process used also defines the flexibility of the display.

The somewhat confusing part is that Samsung’s AMOLED displays use plastic substrates. And as the name suggests, LG Display’s POLED technology clearly uses plastic as well. In summary, it’s absolutely possible to build a plastic substrate, active-matrix OLED panel. That’s exactly what both of the big two panel manufacturers are doing when it comes to mobile displays.

Even though LG and Samsung-made OLED panels qualify as both POLED and AMOLED simultaneously, the companies aren’t exactly producing identical panels. The quality of the TFT layer and plastic compound can make a difference to display performance, as can the type of emitters and sub-pixel layout.

Different color LEDs offer different brightnesses and shelf life. Blue emitters, for example, degrade the quickest. Panel manufacturers can therefore opt to use different LED materials – such as small-molecule, polymer, or phosphorescent – to optimize their designs. This may also necessitate different subpixel layouts in order to balance the panel white color, gamut, and resolution.

Over the years, we’ve seen OLED display manufacturers converge on a set of standard parameters. For example, both LG and Samsung use a diamond PenTile sub-pixel layout for smartphone displays. This just means that both should offer similar long-term reliability.

Even when it comes to other attributes like power consumption, brightness, low brightness performance, and panel uniformity, it’s unclear if one has an upper hand. That said, most smartphone makers — from Apple to OnePlus — turn to Samsung’s AMOLED panels for their flagship devices.

In the past, LG used POLED displays in its own flagship smartphones like the Velvet and Wing. However, these panels fell slightly short of the competition in certain aspects like peak brightness and color gamut coverage. These shortfalls led to speculations that Samsung has a leg up over the competition, but the accuracy of these claims is anyone’s guess.

So does that mean you should avoid POLED? Not quite — it’s still fundamentally OLED technology, which offers numerous advantages over IPS LCD. Moreover, you’ll mostly find POLED displays in mid-range and budget smartphones these days, where they should have no problem matching Samsung’s own lower-end AMOLED panels. As a relatively smaller player, LG may also offer more competitive pricing as compared to Samsung.

For most consumers, the choice of POLED vs AMOLED will be of little consequence. The underlying principle – an active-matrix OLED on a flexible plastic substrate – applies equally to both, after all. Despite the different names, LG Display and Samsung aren’t worlds apart in their approach to producing OLED panels for smartphones.

It can be argued that the display on your smartphone is its most important feature, as it is the principle way in which you interact with your device. A poor display means a poor user experience. As with all tech, it is easy to spot an under-performer, however the differences between a good display and a truly excellent display are harder to discern.

Roughly speaking there are two main types of displays used in smartphones: LCD and LED. These two base technologies have been refined and tweaked to give us AMOLED and IPS LCD. The former stands for Active Matrix Organic Light-Emitting Diode, while the latter means In-Plane Switching Liquid Crystal Display.

All of this hasn’t gone unnoticed by the marketing people, which means that plain old AMOLED or regular IPS LCD aren’t the terms used in the marketing fluff. Instead, we have Super AMOLED, Dynamic AMOLED, Super LCD, Super Retina OLED, Super Retina XDR, Infinity Display, and so on. But what’s any of that actually mean?

The LED part of AMOLED stands for Light Emitting Diode. It’s the same tech as you find on many home appliances that show that the power is on with a little red light. An LED display takes this concept, shrinks it down, and arranges the LEDs in red, green, and blue clusters to create an individual pixel.

The O in AMOLED stands for organic. It refers to a series of thin organic material films placed between two conductors in each LED. These produce light when a current is applied.

Finally, the AM part in AMOLED stands for Active Matrix, rather than a passive matrix technology. In a passive matrix, a complex grid system is used to control individual pixels, where integrated circuits control a charge sent down each column or row. But this is rather slow and can be imprecise. Active Matrix systems attach a thin film transistor (TFT) and capacitor to each sub-pixel (i.e. red, green, or blue) LED. The upshot is that when a row and column is activated, the capacitor at the pixel can retain its charge in between refresh cycles, allowing for faster and more precise control.

The image above is a close-up shot of the AMOLED display on the Samsung Galaxy S8. The RGB triangular pattern is clearly shown. Towards the bottom of the image, the green and red LEDs are off and the blue LEDs are on only slightly. This is why AMOLED displays have deep blacks and good contrast.

Super AMOLED is a marketing term from Samsung. It means a display that incorporates the capacitive touchscreen right in the display, instead of it being a separate layer on top of the display. This makes the display thinner.

Dynamic AMOLED is another marketing term from Samsung. It denotes Samsung’s next-generation AMOLED display which includes HDR10+ certification. According to Samsung, Dynamic AMOLED also reduces the harmful blue light emitted from the display, which helps reduce eye strain and helps lessen sleep disturbances if you’re using your phone late in the day!

As for Infinity Display (or Infinity-O Display), it is more marketing from Samsung. It means “a near bezel-less, full-frontal, edge-to-edge” display. However, it is still a Super AMOLED unit.

LCD displays work with a backlight that shines through some polarizing filters, a crystal matrix, and some color filters. Liquid crystals untwist when an electric charge is applied to them, which affects the frequency of the light that can pass through. Since the crystals can be twisted to varying degrees depending on the voltage used, a display can be built when they are used with polarized panels. A grid of integrated circuits is then used to control each pixel, by sending a charge down into a specific row or column. Colors are created by the use of red, green, and blue filters, known as sub-pixels, which are then blended by varying degrees to produce different colors.

The above image is of an LCD display from a Huawei Mate 8. Notice how the pixels are made up of equally-sized sub-pixels, one for each of the colors: red, green, and blue.

Pixels can suffer from lower aperture at higher resolutions, as transistor sizes can’t be shrunk further, reducing peak brightness and wasting energy.

Like Super AMOLED, a Super LCD display also incorporates the touchscreen. There is no “air gap” between the outer glass and the display element, which means it has similar benefits to Super AMOLED.

Samsung isn’t the only company that is good at marketing, there is another! Apple has coined the term “Retina” for its displays. The term was first used for its smartphones with the launch of the iPhone 4, as it offered a significantly greater pixel density (over 300 ppi) when compared to the iPhone 3GS. Later came Retina HD, which applies to iPhones with at least a 720p screen resolution.

All Retina and Retina HD displays on the iPhone are LCD IPS displays. However, things have changed a bit with the iPhone X as it features an AMOLED display, now marketed under the term Super Retina. It’s still an AMOLED display. It just has extra adjectives. With the launch of the iPhone 11 Pro, Apple coined the term Super Retina XDR. The XDR part means Extended Dynamic Range, as they have better contrast ratios and higher peak brightness.

Not all Retina displays use OLED. Although the MacBook Pro is marketed with a “Retina” display, as you can see from the magnified image above, it is a regular LCD, even if it uses the latest Apple silicon.

Both technologies can be used to build displays with 720p, 1080p, Quad HD, and 4K resolutions. And OEMs have made handsets that support HDR10 using both LCD and AMOLED displays. So from that point of view, there isn’t much difference between the two.

When it comes to color, we know that the blacks will be deeper and the contrast ratios higher on AMOLED displays. But, overall color accuracy can be high on both types of display.

One of the main weaknesses of AMOLED displays is the possibility of “burn-in”. This is the name given to a problem where a display suffers from permanent discoloration across parts of the panel. This may take the form of a text or image outline, fading of colors, or other noticeable patches or patterns on the display. The display still works as normal, but there’s a noticeable ghost image or discoloration that persists. It occurs as a result of the different life spans between the red, green, and blue LED sub-pixels used in OLED panels.

Blue LEDs have significantly lower luminous efficiency than red or green pixels, which means that they need to be driven at a higher current. Higher currents cause the pixels to degrade faster. Therefore, an OLED display’s color doesn’t degrade evenly, so it will eventually lean towards a red/green tint (unless the blue sub-pixel is made larger, as you can see in the first image in this post). If one part of the panel spends a lot of time displaying a blue or white image, the blue pixels in this area will degrade faster than in other areas.

The theoretical lifespan of an AMOLED display is several years, even when used for 12 hours a day. However, there is anecdotal evidence that some displays suffer from burn-in quicker than others. Displays that show signs of burn-in after only a few months should be considered defective because they certainly aren’t normal.

While owners of devices with LCD screens might congratulate themselves for picking a smartphone that is immune to burn-in, there can be a problem with LCD panels called “image retention.” Put simply, liquid crystals can develop a tendency to stay in one position when left at the same voltage for extended periods. Thankfully this phenomenon is normally temporary and can usually be reversed by allowing the liquid crystals to return to their relaxed state.

Picking a winner can be hard as there are many factors to consider, not only about the display technologies but also about the other components in a handset. For example, if you are an AMOLED fan, then would you consider a device with large storage and a good processor, but with an LCD display? The same argument works the other way for LCD fans. Generally, you’ll be fine with either display type, so just pick the handset you like.

Higher-end devices typically sport AMOLED displays and mid-range/budget devices usually use LCD. But that isn’t set in concrete as there are plenty of high-end devices that have LCD displays. With OLED production costs dropping dramatically in recent years, more and more budget options will be offering OLED panels in the future.

Companies like LG and Samsung have seen this trend coming and are rapidly expanding their OLED (and flexible OLED) production capabilities. LCD might still have a bright future in televisions and other large-panel applications, but for now, it looks like mobile will be increasingly dominated by OLED screens.

What do you think? AMOLED or LCD? What about the terms like Retina vs Infinity Display? Are they meaningful to you? Please let me know in the comments below.

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AMOLED is Active Matrix Organic Light Emitting Diode. Its core part is still LED.It’s very common to see LED in daily life.There are many small size of LEDs on the screen,and they are divided into three sub-pixels of red, green and blue. Then different colors are combined, and the arrangement of sub-pixels will directly affect the whole display effect.The “O” of AMOLED stands for Organic, which means a series of organic thin film materials are used between the positive and negative electrodes to achieve the purpose of luminescence.

The advantage of OLED screens is pixels can be highly controlled, each of them are independently controlled to achieve better contrast ratio. In addition, turning off unnecessary pixels when show the picture,also could get lower power consumption.Further,simple structure and good transparency,which are conducive to OLED achieve higher brightness and wider viewing angle.

Displays such as LCD and LED have become indispensable for technological devices. Over time, various upgrades were made. These screens are mostly used on smartphones.

A smartphone usually has a Touch screen interface, and therefore display technology is more compatible with image quality. Manufacturers are trying to offer better, brighter and more vivid displays.

IPS LCD is a modified version of the old LCD and was developed to overcome its limitations. You probably remember using a phone with a flat old LCD screen. It doesn"t give much of a screen experience. Colors disappeared when looking from another direction, and image quality was blurred due to low color reproduction.

AMOLED has an active Organic LED matrix. They consist of an electroluminescent layer of organic compounds. Electricity produces light when passed through a Thin Film containing organic compound.

The IPS needs good backlight to produce a suitable polarized light. This gives us brighter white and good visibility in sunlight. It also provides good screen clarity. The power consumption of the IPS LCD is almost 5% higher than that of the AMOLED.

AMOLED gives good blacks because it does not require an external backlight. Organic compounds produce light in contact with electricity. For blacks it usually turns off the transistor, so no electricity is required. In addition, the LED emits light without generating heat, which minimizes energy loss due to heat.

AMOLED produces a good amount of black that gives high contrast to the images produced. The image appears bright and vivid, but can sometimes make the color look slightly saturated. It also has a higher refresh rate, allowing you to watch high-definition videos. AMOLEDs give the human eye less harmful light than the IPS LCD.

On the other hand, the IPS LCD has a great color reproduction. Whites are much better than AMOLED, which looks a little yellowish. Adds natural color to other sections. The electric field changes the quality of the behavior of the liquid crystal to achieve good crystallization angles.

Of course, among the display technologies, the cost of AMOLEDs is very high. The materials required to make the screen are very expensive. Mostly Samsung"s high-end devices have AMOLED displays. IPS LCD has a higher cost than the development of the TFT LCD. However, it is not as expensive as AMOLED. IPS LCDs are also used by some of the renowned phone manufacturers, such as Apple (previous iPhone 8, 7 and similar versions) and HTC.

AMOLED uses organic compounds for electroluminescence. These organic compounds tend to fade after prolonged use. Red and Green pixels have a longer life than blue. This is Red, Blue, Green, the basic pixel that gives us a very traceable color. Therefore, fading of one of the basic pixels may result in a significant color change. In contrast, the liquid crystals on the IPS LCD display help to ensure long life.

The comparison between the IPS LCD and the AMOLED is somewhat trivial. Because both screens have good points on their own. Of course, we do not select such screens, depending on the manufacturer. The ever-evolving technology will somehow open the door to new ones.

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OLED displays are commonplace on all high-end phones, tablets, smartwatches, televisions, and even many of the many budget phones. However, there isn"t one type of OLED technology. Depending on your device, you may have an OLED, AMOLED, or POLED display.

OLED promises inky blacks, high contrast, low response times, and incredible brightness. There are a few downsides (primarily the burn-in phenomenon), but overall it"s the best screen technology you"ll find. We explain the background behind the acronyms, the difference between POLED and AMOLED, and which is better, helping you choose the right phone.

Before we get into the differences between the types of OLED screens, let"s look at the similarities. Regardless of your OLED device, whether a laptop or a smartphone, there are some standard fundamentals.

Every OLED screen comprises millions of diodes, hence the name organic light-emitting diode. Viewed under a microscope, each screen consists of a series of red, green, and blue diodes that can be individually turned on and off. Behind this, the light-emitting pixels of an OLED display emit blue and yellow light. The yellow and blue light combine to form white light, passing through the red, green, and blue subpixels to produce a single pixel. Because each pixel handles its light and color, OLED displays do not need a separate backlight.

As an OLED screen doesn"t need a backlight, black is produced by turning off the pixels, resulting in deep, consistent blacks. This allows manufacturers to implement things like an always-on display without quickly burning through battery life.

Another critical advantage of OLED tech is high contrast ratios. Technically, OLED displays offer "infinite contrast," or 1,000,000:1 contrast ratios. This is because OLED displays reproduce black by turning off pixels entirely, and contrast is measured by comparing the brightest part of the screen to the darkest part. Improved contrast makes on-screen content more vivid and makes bright highlights look more impressive. This also means that OLED screens can reach higher brightness than the best IPS LCD screens.

OLED displays can display more colors with greater color accuracy than their LCD peers. This is great for photographers and videographers using their phones to preview, edit, and create content.

OLED displays have near-instantaneous pixel response times. Older LCD screens often have lower response times because to change from one color to another, they must physically change the orientation of a liquid crystal, which takes time. An OLED display turns a subpixel on or off with an electrical charge, giving them a faster pixel response time.

The omission of a separate backlight and the use of fewer components means OLED displays can be thinner than LCDs, making them more versatile in their applications. This means they are more fragile and prone to damage in high-impact or high-stress situations. Engineers combat this by using technologies like Gorilla Glass and robust metal frames. Mitigation strategies like these raise the cost of OLED screens.

OLED displays can also be transparent, depending on the materials used. Transparent displays are helpful for in-display fingerprint readers and under-display cameras, which allow manufacturers to design smartphones with fewer and smaller bezels, notches, and display cutouts. When notches and cutouts are necessary, OLED displays have more even brightness around those cutouts and notches compared with LCDs, where the backlight has to make it around the cutout, and things get a little messy.

Of particular import to smartphones, OLED displays often consume less power, especially when displaying dark images or UI elements, thanks to the pixel-level regulation of brightness. However, at max brightness, an OLED screen usually uses more power than an equivalent LCD.

As with any new technology, OLED tech is not without its flaws.OLED displays are prone to degradation from age and UV exposure, resulting from the organic nature of the molecules that make up the diodes. The organic nature of OLED displays also leads to a phenomenon called screen burn-in, where static UI elements like menus, navigation bars, and status bars (elements that are on-screen for long periods) leave a permanent ghost image, even when they are not displayed. However, burn-in has been somewhat mitigated by pixel shifting and technological advancements in recent years.

Early OLED screens placed all the organic materials on a glass substrate. However, glass is rigid, so a flexible plastic substrate is needed to create foldable display screens, leading to the creation of POLED screens.

POLED (polymer organic light-emitting diode) offers advantages in terms of durability and versatility. The replacement ofglass substrates with plastic ones makes them more shock-resistant. Another unique advantage is in the implementation. Designers can reduce bezel size by folding the electronics underneath an edge of the display instead of having it be on the same plane. POLED displays are also significantly thinner than OLED displays with glass substrates.

Note the difference between P OLED and pOLED. pOLED is the trademark that LG Display uses to brand its plastic OLED displays. It produces these displays for a variety of applications and companies. Google used pOLED displays on the Pixel 2 XL, LG used them on theLG Velvet and several wearables,and Apple reportedly used LG pOLED displays on some Apple Watch models. LG"s pOLED displays seem to suffer from an increased risk of burn-in, as users of the Google Pixel 2 XL complained of burn-in after a few months of use.

To get to the resolution and size of a phone, an AMOLED screen (active matrix organic light emitting diode) is needed. Older, passive matrix OLED displays (PMOLED) require higher voltages for higher pixels/resolutions. The higher the voltage, the lower the screen"s lifetime.

Thin-film transistor (TFT) arrays used in modern active-matrix OLED displays control the charging of the display"s storage capacitors. These TFTs control current flow, resulting in more energy-efficient OLED panels than PMOLED displays. This allows a larger display size without compromising resolution, lifetime, or power consumption.

QLED isn"t related to OLED displays—despite what the name may suggest—but it"s often slated as a competitor to OLED, and it aims to replace the technology by targeting both OLED"s successes and failures. QLED stands for quantum dot light-emitting diode. The core principle of QLED technology is the same as a regular OLED. A backlight is passed through red, green, and blue subpixel layers to generate an image. However, the backlight isn"t one large, uniformly-lit layer. Instead, QLED displays use an array of tiny individually-controlled LEDs to supply the backlight. Using individually-controlled LEDs means the display can produce a more accurate image with a higher contrast.

Generally speaking, QLED displays have similar benefits to OLED displays—high peak brightness, high contrast, perfect blacks, and good saturation. Still, they lack some OLED advantages, like image retention and reduced overall and sustained brightness.

QLED is found in TVs and large computer monitors because that"s where it sees the most benefit. OLED displays in phones are small enough, bright enough, and cheap enough that QLED wouldn"t be able to compete or offer any practical benefit to the end user.

Display type is only one part of the puzzle.What use is exotic technology if it doesn"t make any difference to the end user? Smartphone manufacturers use many approaches to improve their displays. Let"s look at a few things you should look for apart from the display type.

Resolution is the number of pixels a screen has. It is usually written as a ratio: pixels on the long side by pixels on the short side, for example, 1920 x 1080. Most smartphone displays have a resolution between 720p (1280 x 720) on the low-end and 4k (3480 x 2160) on some Sony models. While 4k is excessive and rare for anything under 15 inches, 720p, 1080p, and 1440p are all common smartphone resolutions.

The ideal smartphone screen resolution depends on the screen size. A metric called pixels per inch (PPI) describes the display"s number of pixels in a vertical or horizontal inch. For a 6-inch display, you should aim for at least 1080p or above 350 PPI. This will ensure that the text is crisp.

A subpixel is one of the light-emitting parts of a pixel—in the case of most displays, these are red, blue, and green—that combine in different quantities to display various colors in an image. Although RGB subpixel layouts have been the prevalent option for a long time, some display manufacturers elect to use subpixel arrangements like BGR, PenTile, RGBG, and WRGB. The reason these subpixel layouts exist is to combat the various shortcomings of the display technology.

As with resolution, the subpixel layout can affect perceived image quality. Over the brief course of display history, manufacturers and designers have settled on RGB as a standard, meaning content is generally optimized for that layout. When manufacturers decided to invent new subpixel layouts, the perceived quality took a bit of a hit.

So why do manufacturers use odd-pixel layouts? It depends on the manufacturer and its goals. Samsung uses PenTile displays, which use RGBG instead of RGB subpixels, to combat image retention on its AMOLED displays. WRGB displays add a separate white subpixel to boost brightness on OLED displays—a technology that is otherwise notoriously dim.

There are reasons for these odd layouts. PenTile, for example, increases the number of green subpixels to reduce the effect of burn-in and increase panel lifespan. Still, many people are sensitive to the decreased resolution and clarity that often results from unorthodox subpixel layouts. Part of these resolution problems lies in subpixel antialiasing, which works on a subpixel basis to smooth out text and on-screen elements. Some do this better than others, which is why an iPhone 13"s screen seems sharper than the competition. However, even Samsung acknowledges that PenTile layouts suffer in terms of resolution and clarity.

When it comes to smartphones, the pixel density is so high you won"t notice a slight reduction in quality from a change in the subpixel layout. Whereas, you"ll probably see the green subpixels dying out more quickly than the others, meaning PenTile and its friends are probably here to stay until an alternative arrives.

Refresh rate is the number of times per second a display refreshes, and higher refresh rates mean motion and animations look smoother. Generally, 60Hz is the lowest commonly-found refresh rate and is perfectly serviceable. Many modern flagship phones and a few mid-range phonesoffer 90Hz, 120Hz, 144Hz, and even 240Hz displays.

While a 90Hz or 120Hz refresh rate will be noticeable in everyday use, anything above that should be reserved for gaming since it will not be a noticeable change. A higher refresh rate will impact battery performance, so it is crucial to find a balance. Options like variable and adaptive refresh rate technology enable high refresh rates without battery compromises.

Response times on OLED displays are generally lower, meaning displays can reach these high refresh rates and look better at these higher refresh rates thanks to the reduced ghosting.

Smartphones are often used outside in bright sunlight, so display brightness is a huge factor. Display brightness is measured in nits or cd/m². Peak brightness is the momentary maximum brightness of a small portion of a screen, while sustained brightness is a more realistic representation of the brightness of the whole display. Aim for above 600 nits of sustained brightness since anything below may cause legibility issues in bright conditions. On the other hand, brightness is measured logarithmically, not linearly, meaning 1,200 nits is only twice as bright as 300 nits. This is important since many manufacturers lean heavily on high brightness metrics as a marketing point.

Display specifications are no different. While it is true that OLED displays may be the best option for some people, they command a premium, and a lot of people wouldn"t notice the difference.

Brightness, refresh rate, and resolution are all key factors, and performance as a whole should be the determining factor in selecting a display, not the shiny new technology involved. If you"re looking for a phone with an OLED display and a high refresh rate, check out the best Android phones you can buy.

In recent years, smartphone displays have developed far more acronyms than ever before with each different one featuring a different kind of technology. AMOLED, LCD, LED, IPS, TFT, PLS, LTPS, LTPO...the list continues to grow.

As if the different available technologies weren"t enough, component and smartphone manufacturers adopt more and more glorified names like "Super Retina XDR" and "Dynamic AMOLED", which end up increasing the potential for confusion among consumers. So let"s take a look at some of these terms used in smartphone specification sheets and decipher them.

There are many display types used in smartphones: LCD, OLED, AMOLED, Super AMOLED, TFT, IPS and a few others that are less frequently found on smartphones nowadays, like TFT-LCD. One of the most frequently found on mid-to-high range phones now is IPS-LCD. But what do these all mean?

LCD means Liquid Crystal Display, and its name refers to the array of liquid crystals illuminated by a backlight, and their ubiquity and relatively low cost make them a popular choice for smartphones and many other devices.

LCDs also tend to perform quite well in direct sunlight, as the entire display is illuminated from behind, but does suffer from potentially less accurate colour representation than displays that don"t require a backlight.

Within smartphones, you have both TFT and IPS displays. TFT stands for Thin Film Transistor, an advanced version of LCD that uses an active matrix (like the AM in AMOLED). Active matrix means that each pixel is attached to a transistor and capacitor individually.

The main advantage of TFT is its relatively low production cost and increased contrast when compared to traditional LCDs. The disadvantage of TFT LCDs is higher energy demands than some other LCDs, less impressive viewing angles and colour reproduction. It"s for these reasons, and falling costs of alternative options, that TFTs are not commonly used in smartphones anymore.Affiliate offer

IPS technology (In-Plane Switching) solves the problem that the first generation of LCD displays experience, which adopts the TN (Twisted Nematic) technique: where colour distortion occurs when you view the display from the side - an effect that continues to crop up on cheaper smartphones and tablets.

The PLS (Plane to Line Switching) standard uses an acronym that is very similar to that of IPS, and is it any wonder that its basic operation is also similar in nature? The technology, developed by Samsung Display, has the same characteristics as IPS displays - good colour reproduction and viewing angles, but a lower contrast level compared to OLED and LCD/VA displays.

According to Samsung Display, PLS panels have a lower production cost, higher brightness rates, and even superior viewing angles when compared to their rival, LG Display"s IPS panels. Ultimately, whether a PLS or IPS panel is used, it boils down to the choice of the component supplier.

This is a very common question after "LED" TVs were launched, with the short answer simply being LCD. The technology used in a LED display is liquid crystal, the difference being LEDs generating the backlight.

Despite the improvement in terms of contrast (and potentially brightness) over traditional LCD/LED displays, LCD/mini-LEDs still divide the screen into brightness zones — over 2,500 in the case of the iPad and 2021 "QNED" TVs from LG — compared to dozens or hundreds of zones in previous-generation FALD (full-array local dimming) displays, on which the LEDs are behind the LCD panel instead of the edges.

AMOLED stands for Active Matrix Organic Light-Emitting Diode. While this may sound complicated it actually isn"t. We already encountered the active matrix in TFT LCD technology, and OLED is simply a term for another thin-film display technology.

OLED is an organic material that, as the name implies, emits light when a current is passed through it. As opposed to LCD panels, which are back-lit, OLED displays are "always off" unless the individual pixels are electrified.

This means that OLED displays have much purer blacks and consume less energy when black or darker colours are displayed on-screen. However, lighter-coloured themes on AMOLED screens use considerably more power than an LCD using the same theme. OLED screens are also more expensive to produce than LCDs.

Because the black pixels are "off" in an OLED display, the contrast ratios are also higher compared to LCD screens. AMOLED displays have a very fast refresh rate too, but on the downside are not quite as visible in direct sunlight as backlit LCDs. Screen burn-in and diode degradation (because they are organic) are other factors to consider.Affiliate offer

OLED stands for Organic Light Emitting Diode. An OLED display is comprised of thin sheets of electroluminescent material, the main benefit of which is they produce their own light, and so don"t require a backlight, cutting down on energy requirements. OLED displays are more commonly referred to as AMOLED displays when used on smartphones or TVs.

As we"ve already covered, the AM part of AMOLED stands for Active Matrix, which is different from a Passive Matrix OLED (P-OLED), though these are less common in smartphones.

Super AMOLED is the name given by Samsung to its displays that used to only be found in high-end models but have now trickled down to more modestly specced devices. Like IPS LCDs, Super AMOLED improves upon the basic AMOLED premise by integrating the touch response layer into the display itself, rather than as an extra layer on top.

As a result, Super AMOLED displays handle sunlight better than AMOLED displays and also require less power. As the name implies, Super AMOLED is simply a better version of AMOLED. It"s not all just marketing bluster either: Samsung"s displays are regularly reviewed as some of the best around.

The latest evolution of the technology has been christened "Dynamic AMOLED". Samsung didn"t go into detail about what the term means, but highlighted that panels with such identification include HDR10+ certification that supports a wider range of contrast and colours, as well as blue light reduction for improved visual comfort.

In the same vein, the term "Fluid AMOLED" used by OnePlus on its most advanced devices basically highlights the high refresh rates employed, which results in more fluid animations on the screen.Affiliate offer

The technology debuted with the obscure Royole FlexPai, equipped with an OLED panel supplied by China"s BOE, and was then used in the Huawei Mate X (pictured above) and the Motorola Razr (2019), where both also sport BOE"s panel - and the Galaxy Flip and Fold lines, using the component supplied by Samsung Display.Affiliate offer

Resolution describes the number of individual pixels (or points) displayed on the screen and is usually presented for phones by the number of horizontal pixels — vertical when referring to TVs and monitors. More pixels on the same display allow for more detailed images and clearer text.

To make it easier to compare different models, brands usually adopt the same naming scheme made popular by the TV market with terms like HD, FullHD and UltraHD. But with phones adopting a wide range of different screen proportions, just knowing that is not enough to know the total pixels displayed on the screen.Common phone resolutions

But resolution in itself is not a good measure for image clarity, for that we need to consider the display size, resulting in the pixel density by area measured by DPI/PPI (dots/points per inch).Affiliate offer

Speaking of pixel density, this was one of Apple"s highlights back in 2010 during the launch of the iPhone 4. The company christened the LCD screen (LED, TFT, and IPS) used in the smartphone as "Retina Display", thanks to the high resolution of the panel used (960 by 640 pixels back then) in its 3.5-inch display.

The name coined by Apple"s marketing department is applied to screens which, according to the company, the human eye is unable to discern the individual pixels from a normal viewing distance. In the case of iPhones, the term was applied to displays with a pixel density that is greater than 300 ppi (dots per inch).

With the iPhone 11 Pro, another term was introduced to the equation: "Super Retina XDR". Still using an OLED panel (that is supplied by Samsung Display or LG Display), the smartphone brings even higher specs in terms of contrast - with a 2,000,000:1 ratio and brightness level of 1,200 nits, which have been specially optimized for displaying content in HDR format.

As a kind of consolation prize for iPhone XR and iPhone 11 buyers, who continued relying on LCD panels, Apple classified the display used in the smartphones with a new term, "Liquid Retina". This was later applied also to the iPad Pro and iPad Air models, with the name defining screens that boast a high range and colour accuracy, at least based on the company"s standards.

Nit, or candela per square meter in the international system (cd/m²), is a unit of measurement of luminance, i.e. the intensity of light emitted. In the case of smartphone screens and monitors in general, such a value defines just how bright the display is - the higher the value, the more intense the light emitted by the screen.

The result is smoother animations on the phone, both during regular use and in games, compared to screens that have a 60 Hz refresh rate which remains the standard rate in the market when it comes to displays.

Originally touted to be a "gimmick" in 2017, with the launch of the Razer Phone, the feature gained more and more momentum in due time, even with a corresponding decrease in battery life. In order to make the most of this featur