foldable lcd display manufacturer

They are easy to create and customizable, and foldable lcdds are available in a variety of sizes. Whether you are looking for wholesale foldable lcdds for retailers or customers who want to buy in bulk for a retail price or a retailer, Alibaba.com has a wide variety of foldable lcdds available from various sellers.

Foldable OLED displays can be bent by the user. These innovative displays enable new form factors, such as - such as phones that open into tablets, smart bands that open into smartphones and laptops with large displays. In 2019 the first foldable smartphones were launched, and after a rocky start, device markers are now introducing new devices to market as analysts expect increased adoption in the future.

In 2019 Samsung finally introduced the first device, the Galaxy Fold - which had a problematic launch. Since then Samsung followed up with several new foldable phones, for example the Galaxy Z Fold 2 which sports an internal foldable display at 7.6" 1768x2208 HDR10+ 120Hz Dynamic AMOLED and also a larger 6.23" 816x2260 Super AMOLED cover display. Samsung also launched the clamshell-style Galaxy Z Flip.

Several companies offer foldable phones besides Samsung, including Motorola, Huawei and others. Huawei for example launched the Mate X2 in 2021, which features an inside-folding AMOLED display, a 8-inch 90Hz 2480 x 2200 one. There is also an external 6.45-inch 1160 x 2700 90Hz (240Hz touch sampling rate) AMOLED display.

Foldable OLED laptops is another promising market segment. In 2021 Lenovo started shipping the $2,499 foldable ThinkPad X1 Fold laptop, with its 13.3" 2048x1536 foldable OLED display (produced by LG Display). Hopefully more companies will follow suit and we"ll see more such devices on the market soon.

If you want to learn more about the foldable OLED technology, industry and market, check out ourWhy flexible displays and lighting panels are so exciting

FlexEnable’s glass-free organic LCD (OLCD) delivers high-brightness, long lifetime flexible displays that are low cost and scalable to large areas, while also being thin, lightweight and shatterproof.

OLCD is a plastic display technology with full colour and video-rate capability. It enables product companies to create striking designs and realise novel use cases by merging the display into the product design rather than accommodating it by the design.

Unlike flexible OLED displays, which are predominantly adopted in flagship smartphones and smartwatches, OLCD opens up the use of flexible displays to a wider range of mass-market applications. It has several attributes that make it better suited than flexible OLED to applications across large-area consumer electronics, smart home appliances, automotive, notebooks and tablets, and digital signage.

OLCD can be conformed and wrapped around surfaces and cut into non-rectangular shapes during the production process. Holes can be also added to fit around the functional design of the system – for example around knobs and switches.

As with glass-based LCD, the lifetime of OLCD is independent of the display brightness, because it is achieved through transmission of a separate light source (the backlight), rather than emission of its own light. For example OLCD can be made ultra-bright for viewing in daylight conditions without affecting the display lifetime – an important requirement for vehicle surface-integrated displays.

OLCD is the lowest cost flexible display technology – it is three to four times lower cost that flexible OLED today. This is because it makes use of existing display factories and supply chain and deploys a low temperature process that results in low manufacturing costs and high yield.

Unlike other flexible display approaches, OLCD is naturally scalable to large sizes. It can be made as small or as large as the manufacturing equipment used for flat panel displays allows.

The flexibility of OLCD allows an ultra-narrow bezel to be implemented by folding down the borders behind the display. This brings huge value in applications like notebooks and tablets where borderless means bigger displays for the same sized device. The bezel size allowed by OLCD is independent of the display size or resolution. In addition, OLCD can make a notebook up to 100g lighter and 0.5mm thinner.

OLCD is the key to the fabrication of ultra-high contrast dual cell displays with true pixel level dimming, offering OLED-like performance at a fraction of the cost. The extremely thin OLCD substrate brings advantages in cost, viewing angle and module thickness compared to glass displays. At the same time OLCD retains the flexibility required for applications such as surface-integrated automotive displays.

Due to its unique properties, OLCD has the potential to transform how and where displays are used in products. The videos below give a glimpse into this innovative technology.

OLCD brings the benefits of being thin, light, shatterproof and conformable, while offering the same quality and performance as traditional glass LCDs. The mechanical advantages of plastic OLCD over glass LCD are further enhanced by the technology’s excellent optical performance, much of which originates from the extreme thinness of plastic TAC substrates compared to glass.

This year has seen no shortage of rollable display demos from manufacturers, and now Samsung Display is the latest company to show off new concepts for folding and sliding screens. SamMobile spotted the concepts being showcased as part of a virtual Display Week exhibition (if you forgot to mail out your Happy Display Week cards, there’s still time since it runs through Friday) including a “multi-foldable” mobile display and a large 17-inch folding screen.

The company calls its first concept S-foldable, with a bi-fold design that opens up to a maximum screen size of 7.2 inches. It’s similar to the Galaxy Z Fold 2 except, well, plus one fold. There’s also a sliding mobile display similar to the ill-fated rollable concept LG showed off earlier this year before leaving the smartphone space altogether.

Samsung Display is also showing two concepts for bigger panels, including a 17-inch foldable OLED that’s tablet-sized when folded and can function as a monitor when unfolded. Finally, there’s a more traditional-looking laptop display; it doesn’t fold or flex, but it does include an under-display camera — hopefully it’s better than the last one we used.

Samsung Display is a division of Samsung Electronics, and it produces OLED panels for use by Samsung and other consumer tech manufacturers. So while these concepts may end up in future Samsung products, it’s certainly not guaranteed. The company as a whole hasn’t been shy about embracing foldable technology, getting into the foldable device market early. It may have more company soon; display OEM TCL has shown off its own concepts and says it will bring one to market this year. Until then, we’ll be watching and filling out our foldable concept bingo cards.

Panox Display provides free connectors for clients who purchase more than five products from us. Our product range includes connectors from Molex, Kyocera, AXE, AXG, JAE, Hiros, and more.

Panox Display provides a customized cover glass/touch panel service. We supply cover glass from Gorilla, AGC, and Panda, which all have excellent optical performance. We also supply driver ICs from Goodix and Focaltech.

If your applications are directly connected to a PC, a cellphone, or Raspberry Pi, and you have enough space to insert a board to input video, Panox Display can provide customized Controller/Driver boards with input connections for VGA, HDMI, DVI, DP, Type-C video input, MIPI, RGB, LVDS, and eDP.

There has been a significant shift in the global display industry lately. Apart from new display technologies, the display world is now dominated by players in Asian countries such as China, Korea, and Japan. And rightly so, the world’s best famous LCD module manufacturers come from all these countries.

STONE Technologies is a proud manufacturer of superior quality TFT LCD modules and LCD screens. The company also provides intelligent HMI solutions that perfectly fit in with its excellent hardware offerings.

STONE TFT LCD modules come with a microcontroller unit that has a Cortex A8 1GHz Standard 256MB. Such a module can easily be transformed into an HMI screen. Simple hexadecimal instructions can be used to control the module through the UART port. Furthermore, you can seamlessly develop STONE TFT LCD color user interface modules and add touch control, features to them.

You can also use a peripheral MCU to serially connect STONE’s HMI display via TTL. This way, your HMI display can supply event notifications and the peripheral MCU can then execute them. Moreover, this TTL-connected HMI display can further be linked to microcontrollers such as:

In this post, we list down 10 of the best famous LCD manufacturers globally. We’ll also explore why they became among the reputable LCD module manufacturers in the world.

Samsung is the world’s largest semiconductor and consumer electronics manufacturer by revenue. The electronics giant is well-known for its smartphones and home appliances, but the company also manufactures LCD, LED, and OLED panels.

Probably the most in-demand and popular display panel product for Samsung is their OLED technology. Most of its current smartphones use their trademark Super AMOLED displays. The technology allowed Samsung’s smartphones to be ultra-thin, with better image brightness, and less energy consumption.

Samsung now produces panels for smart TVs. With their ever-evolving technological expertise and high-quality products, the company shows no signs of slowing down as one of the world’s best famous LCD module manufacturers.

Established in 2004, Stone Technologies has been an emerging giant in the Chinese display industry. The company is headquartered in Beijing, China, and operates its manufacturing plants, sales, product testing, and R&D units from there.

Stone provides a professional product line that includes intelligent TFT-LCD modules for civil, advanced, and industrial use. Furthermore, Stone also creates embedded-type industrial PCs. The company’s products are all highly-reliable and stable even when used with humidity, vibration, and high temperatures.

Stone Technologies caters to a wide range of clients and industries, being among the world’s best famous LCD module manufacturers. The company’s products are used in the following industries:

Originally, LG Display was a joint venture of mother company LG Electronics and the Dutch company Phillips. They dedicated the company to creating active-matrix LCD panels. Another joint venture called LG. Phillips Displays was created to manufacture deflection yokes and cathode ray tubes.

However, Phillips decided to start selling its shares in 2008, and the dwindling company shares of Phillips prompted LG to change its corporate name to LG Display with approval from all existing shareholders.

Today, LG Display is headquartered in Seoul, South Korea. The company has eight manufacturing plants in South Korea, specifically in Paju and Gumi. LG Display also operates one module assembly plant in Wroclaw, Poland, as well as two others in Guangzhou and Nanjing, China.

LG Display has risen above the rest because of its world-class module products. Because of this, the company caters to a massive range of famous clients including Hewlett Packard, Apple, Sony, Dell, Acer, and Lenovo. LG Display also creates LCD modules and similar display panels for the company’s television product range.

Innolux Corporation is another famous LCD module manufacturer. This company was established in 2003 and is currently based in Zhunan, Miaoli County, Taiwan.

The company is a well-known manufacturer of display panels in Taiwan. Innolux supplies TFT-LCD and LED panels, open cells, and touch modules for the following products:

What makes Innolux stand out from other LCD module manufacturers is the company’s commitment to its humanistic qualities. Innolux believes that they are in the business to contribute to the well-being and prosperity of their customers. This is then achieved by creating world-class products that satisfy its clients.

Sharp is a Japanese company founded in 1912. It is now based in Sakai, Osaka Prefecture. The company produces various kinds of electronic products including mobile phones, LCD panels, calculators, PV solar cells, and consumer electronics. Sharp has produced TFT-LCD products as early as the 1980s.

For the regular public consumers, Sharp produces a variety of smart TVs and LCD TVs marketed under the Aquos brand. The company’s television line-up boasts of impressively high-quality technology. The TVs are equipped with technologies that support 4K and 8K UHD display, allowing for a great high-resolution viewing experience.

BOE Display is among the leading display manufacturers in the world. The company started in 1993 and is currently based in Beijing, China. Apart from display panels, BOE also manufactures smart systems using IoT technology.

The company manufactures display products for smartphones, computers, televisions, monitors, tablets, vehicles, wearable devices, and medical equipment. Specifically, here are some of the display products that BOE creates:

BOE’s success in the display industry is mainly due to its innovative technologies and capable manufacturing lines. Furthermore, the company has tied up with several famous clients including Huawei, Motorola, and Apple.

AU Optronics is another global leader in display solution technologies. The company is based in Taiwan and has been in operations since September 2001.

The company proudly utilizes high-end technologies to create world-class display solutions. For instance, AU’s production lines can manufacture a variety of display applications in a full panel size range. The manufacturing lines also support:

Sustainability is among the ultimate goals of AU Optronics. The company takes steps to integrate green solutions into their products for more sustainable development. This commitment to sustainability, among other strong qualities, makes AU Optronics one of the best LCD manufacturers in the world.

Toshiba is a huge Japanese multinational conglomerate company. It was founded in 1939 and is currently based in Minato, Tokyo, Japan. The company is engaged in a wide variety of businesses which also include display solutions for consumer households and industrial use.

Most of these products use TFT-LCD panels alongside other technologies to create ultra-high-definition images. Also, modern Toshiba display products incorporate IoT and artificial intelligence for a smarter product experience.

Kyocera is a Japanese LCD manufacturer. The company started in 1959 as a fine technical ceramics manufacturer but gradually added consumer electronics products to its offerings.

The Japanese company acquired Optrex Corporation in 2012. The acquisition paved the way for creating an R&D center and more production, sales, and marketing bases. Hence, Kyocera’s global LCD business boomed even more.

The company also operates factories, R&D centers, and marketing facilities in Asia, the Middle East, Europe, Africa, North and South America, and Oceania continents. Kyocera has a vast worldwide reach that makes it one of the world’s best famous LCD module manufacturers.

Tianma Microelectronics is a Chinese company specializing in display solutions. The company was established in 1953 and has since been a strong player in both the Chinese and worldwide display solutions industry.

All these high-end technologies make Tianma’s display products suitable for automotive, mobile phones, tablet PCs, industrial screens, avionic displays, medical equipment, and home automation products.

Tianma is committed to creating a colorful life for all, as stated in the company mission. And indeed, the company does not fall short of fulfilling this mission. Tianma continues to create display solutions that fit the needs of several satisfied clients globally.

To wrap all this up, we listed 10 of the world’s best famous LCD module manufacturers. These are all highly-respected companies that built their reputations and climbed up the ladder of LCD module manufacturing. Their quality products, dedication to their craft, and excellent customer service truly make them among the world’s best display solutions providers.

Long-time display manufacturer Samsung Display will likely stop the production of LCD displays this year. A recent report says several factors have influenced the South Korean firm’s decision.

Samsung has been a reputed LCD display manufacturer since 1991. It manufactures panels for its own devices and also works as a supplier for several other Big Tech firms, such as Apple. Its displays are used in virtually all products, ranging from foldable smartphones to televisions and tablets.

Despite the company’s successful business, a recent report from The Korea Times suggests Apple is exiting the LCD production business for good. One of the biggest reasons cited for the decision is the increased competition from Chinese and Taiwanese display manufacturers in the recent past.

Samsung wanted to shut its LCD production late in 2020 and its move was on the cards for a while now. Samsung probably kept its LCD manufacturing facilities operational during the pandemic due to the sudden and unprecedented spike in demand. However, LCD technology has been eclipsed by OLED and QD-OLED technologies on most mainstream devices in the last few years. This is another reason why Samsung will probably shutter the business later this year.

Moreover, research firm Display Supply Chain Consultants (DSCC) believes the average price index of LCD panels measured as 100 in January 2014 will drop down to just 36.6 in September 2022. The figure is indicative of the demand for LCD panels and it plummeted to a record low of 41.5 in April this year. The April figure is a whopping 58 percent lower than the record-high index value of 87 in June 2021 when the pandemic was raging. This reduction in demand and price could also be detrimental to the company’s plans to soldier on producing LCDs.

The report says that in the future, Samsung will remain focused on manufacturing OLED panels and more advanced quantum dot OLED displays. LCD division staffers will likely be transferred to the QD-OLED division. Meanwhile, Samsung Display did not respond to the Korea Times’ request for comment.

We develop, design, manufacture, and sell displays where it is necessary for the interface that deliver a lot of information at an instant and deliver it to the global market. We create interactive spaces that go beyond the expected, elevate everyday lives, and move people"s hearts. From bases in major cities in Asia, Europe, and North America, we build strong customer relationships by developing products that respond to market needs.

Folding screens have become a common sight in recent years, thanks in large part to Samsung’s two lines of foldable phones, the Z Flip and Z Fold. As other manufacturers join in, foldable device prices are quickly going down, promising a new age of personal computing. But how do folding screens actually work?

Whether you’ve always been curious about how folding screens work or have yet to consider it, we’ll give you a crash course in foldable displays and the cool tech that makes them possible.

Simply put, millions of specks of color combine to form the images we see on screen. There are different ways to achieve this, resulting in the various displays you see out there, including LCD, OLED, and, more recently, micro-LED and mini-LED.

Then over the last decade, display manufacturers produced display substrates made of flexible plastic that can bend without breaking. Plastic-based displays made possible the creation of the first phones with curved displays, like the Galaxy Note Edge of 2014.

As technology advanced, display makers figured out ways to increase the amount of flex they could safely build into a screen. Crucially, they also solved the problem of durability, allowing screens to bend thousands of times without breaking. Eventually, this path led us to today’s folding screens, which can fold almost like a sheet of paper.

The flexible substrate is only part of the equation. Scientists and engineers had to solve ridiculously hard problems like manufacturing substrates that are light and flexible but can withstand years of mechanical stress; ensuring that all the bending and folding doesn’t affect image quality over time; creating an equally flexible protective layer for the screen; and making sure that all the other tech that goes into the display still works. When all this was done, other smart people had to devise ways to incorporate the flexible displays into folding phones while maintaining the insanely high standards we expect from our electronics. A very tough job indeed.

Before we look at the individual components of a foldable screen, it’s important to note that all folding screens you see on the market today are of the OLED variety. OLED screens do not have a backlight like LCDs — instead, the pixels themselves emit light when power is applied to them. Because of this, OLEDs can be made about 30% thinner and lighter than LCDs. Coupled with other benefits over LCD, OLED is the first choice for flexible screens, but flexible LCD displays do exist.

To understand how foldable OLED displays function, it’s helpful to visualize the display as a very thin (and probably not very tasty) layer cake. Each layer of this high-tech cake has a specific role. These layers are laminated together in a very thin package that’s fractions of a millimeter thick. Let’s go through them.

Substrate layer — Also called the board, this is the very base of the screen, which supports all the other layers. On a flexible display, the substrate is made of plastic or, less commonly, metal. Most flexible screen devices today use a substrate made of a polymer plastic called polyimide (PI). In addition to being flexible and insulating, polyimide features high mechanical strength and thermal stability.

TFT layer — Applied on top of the flexible substrate, the TFT (thin-film transistor) layer controls power delivery to each pixel. Think of it as a “power grid” that connects all the pixels in the display. On an OLED screen, unlike on LCD, each pixel can be controlled individually, allowing for high contrast rates and lower power consumption.

OLED layer — The light-emitting layer is made up of individual pixels, each of which comprises red, green, and blue subpixels. Each pixel can hit a certain color and luminosity by varying the amount of power its subpixels receive. In turn, pixels combine to form the image we see on the display. The OLED layer is made of several sub-layers, including a cathode, an anode, and a layer of organic light-emitting material sandwiched between them.

Folding screens can be of the in-folding or out-folding variety. On an in-folding display like the Galaxy Z Flip series, the display is hidden inside the device when folded, which helps with durability, but it does tend to create a slight crease on the screen. On an out-folding display (like the Huawei Mate XS 2), the display bends around the outside of the device when folded. That leaves it exposed to scratches, but it provides a crease-free aspect.

Not all flexible display devices fold. We’ve seen devices with rollable displays that roll up and disappear inside the device’s body. Examples include the Oppo X rollable phone or LG’s crazy OLED R rollable TV.

The display is a key aspect of how folding screens work, but it’s not the only one. The hinge may be just as important to the user experience. Manufacturers have poured a lot of resources into ensuring that hinges in their foldable products work smoothly and consistently, have the right amount of “snap,” and provide a smooth surface for the display to sit on.

Another key factor is durability. By definition, foldable screens feature moving parts, which opens up the possibility of water, dust, and other contaminants entering the device. Indeed, we’ve seen issues with debris getting lodged below the screen on some devices, which ruins the user experience and can damage the screen.

Numerous manufacturers have already released or at least teased foldable screen products, including phones, laptops, and even TVs. It’s easy to envision a future where tablets, wearables, gaming consoles, and even home appliances feature screens that bend. Innovation will also come from stretchable, wearable, and even skin-embeddable displays. In the meantime, as more resources are invested in the technology, folding screens will only get better.

A flexible display or rollable display is an electronic visual display which is flexible in nature, as opposed to the traditional flat screen displays used in most electronic devices.e-readers, mobile phones and other consumer electronics. Such screens can be rolled up like a scroll without the image or text being distorted.electronic ink, Gyricon, Organic LCD, and OLED.

Electronic paper displays which can be rolled up have been developed by E Ink. At CES 2006, Philips showed a rollable display prototype, with a screen capable of retaining an image for several months without electricity.pixel rollable display based on E Ink’s electrophoretic technology.flexible organic light-emitting diode displays have been demonstrated.electronic paper wristwatch. A rollable display is an important part of the development of the roll-away computer.

With the flat panel display having already been widely used more than 40 years, there have been many desired changes in the display technology, focusing on developing a lighter, thinner product that was easier to carry and store. Through the development of rollable displays in recent years, scientists and engineers agree that flexible flat panel display technology has huge market potential in the future.

Flexible electronic paper (e-paper) based displays were the first flexible displays conceptualized and prototyped. Though this form of flexible displays has a long history and were attempted by many companies, it is only recently that this technology began to see commercial implementations slated for mass production to be used in consumer electronic devices.

The concept of developing a flexible display was first put forth by Xerox PARC (Palo Alto Research Company). In 1974, Nicholas K. Sheridon, a PARC employee, made a major breakthrough in flexible display technology and produced the first flexible e-paper display. Dubbed Gyricon, this new display technology was designed to mimic the properties of paper, but married with the capacity to display dynamic digital images. Sheridon envisioned the advent of paperless offices and sought commercial applications for Gyricon.

In 2005, Arizona State University opened a 250,000 square foot facility dedicated to flexible display research named the ASU Flexible Display Center (FDC). ASU received $43.7 million from the U.S. Army Research Laboratory (ARL) towards the development of this research facility in February 2004.demonstration later that year.Hewlett Packard demonstrated a prototype flexible e-paper from the Flexible Display Center at the university.

Between 2004–2008, ASU developed its first small-scale flexible displays.U.S. Army funds ASU’s development of the flexible display, the center’s focus is on commercial applications.

This company develops and manufactures monochrome plastic flexible displays in various sizes based on its proprietary organic thin film transistor (OTFT) technology. They have also demonstrated their ability to produce colour displays with this technology, however they are currently not capable of manufacturing them on a large scale.Dresden, Germany, which was the first factory of its kind to be built – dedicated to the high volume manufacture of organic electronics.plastic and do not contain glass. They are also lighter and thinner than glass-based displays and low-power. Applications of this flexible display technology include signage,wristwatches and wearable devices

In 2004, a team led by Prof. Roel Vertegaal at Queen"s University"s Human Media Lab in Canada developed PaperWindows,Organic User Interface. Since full-colour, US Letter-sized displays were not available at the time, PaperWindows deployed a form of active projection mapping of computer windows on real paper documents that worked together as one computer through 3D tracking. At a lecture to the Gyricon and Human-Computer Interaction teams at Xerox PARC on 4 May 2007, Prof. Vertegaal publicly introduced the term Organic User Interface (OUI) as a means of describing the implications of non-flat display technologies on user interfaces of the future: paper computers, flexible form factors for computing devices, but also encompassing rigid display objects of any shape, with wrap-around, skin-like displays. The lecture was published a year later as part of a special issue on Organic User InterfacesCommunications of the ACM. In May 2010, the Human Media Lab partnered with ASU"s Flexible Display Center to produce PaperPhone,MorePhone

Research and development into flexible OLED displays largely began in the late 2000s with the main intentions of implementing this technology in mobile devices. However, this technology has recently made an appearance, to a moderate extent, in consumer television displays as well.

Nokia first conceptualized the application of flexible OLED displays in mobile phone with the Nokia Morph concept mobile phone. Released to the press in February 2008, the Morph concept was project Nokia had co-developed with the University of Cambridge.nanotechnology, it pioneered the concept of utilizing a flexible video display in a consumer electronics device.London, alongside Nokia’s new range of Windows Phone 7 devices.

Sony Electronics expressed interest for research and development towards a flexible display video display since 2005.RIKEN (the Institute of Physical and Chemical Research), Sony promised to commercialize this technology in TVs and cellphones sometime around 2010.TFT-driven OLED display.

In January 2013, Samsung exposed its brand new, unnamed product during the company"s keynote address at CES in Las Vegas. Brian Berkeley, the senior vice president of Samsung"s display lab in San Jose, California had announced the development of flexible displays. He said "the technology will let the company"s partners make bendable, rollable, and foldable displays," and he demonstrated how the new phone can be rollable and flexible during his speech.

During Samsung"s CES 2013 keynote presentation, two prototype mobile devices codenamed "Youm" that incorporated the flexible AMOLED display technology were shown to the public.OLED screen giving this phone deeper blacks and a higher overall contrast ratio with better power efficiency than traditional LCD displays.LCD displays. Samsung stated that "Youm" panels will be seen in the market in a short time and production will commence in 2013.

Samsung subsequently released the Galaxy Round, a smartphone with an inward curving screen and body, in October 2013.Galaxy Note Edge released in 2014.Galaxy S series with the release of the Galaxy S6 Edge, a variant of the S6 model with a screen sloped over both sides of the device.foldable smartphone prototype, which was subsequently revealed in February 2019 as the Galaxy Fold.

The Flexible Display Center (FDC) at Arizona State University announced a continued effort in forwarding flexible displays in 2012.Army Research Lab scientists, ASU announced that it has successfully manufactured the world"s largest flexible OLED display using thin-film transistor (TFTs) technology.

In January 2019, Chinese manufacturer Xiaomi showed a foldable smartphone prototype.Xiaomi demoed the device in a video on the Weibo social network. The device features a large foldable display that curves 180 degrees inwards on two sides. The tablet turns into a smartphone, with a screen diagonal of 4,5 inch, adjusting the user interface on the fly.

Flexible displays have many advantages over glass: better durability, lighter weight, thinner as plastic, and can be perfectly curved and used in many devices.glass and rollable display is that the display area of a rollable display can be bigger than the device itself; If a flexible device measuring, for example, 5 inches in diagonal and a roll of 7.5mm, it can be stored in a device smaller than the screen itself and close to 15mm in thickness.

Flexible screens can open the doors to novel and alternative authentication schemes by emphasizing the interaction between the user and the touch screen. In “Bend Passwords: Using Gestures to Authenticate on Flexible Devices,” the authors introduce a new method called Bend Passwords where users perform bending gestures and deform the touch screen to unlock the phone. Their work and research points to Bend Passwords possibly becoming a new way to keep smartphones secure alongside the popularization of flexible displays.

Flexible displays using electronic paper technology commonly use Electrophoretic or Electrowetting technologies. However, each type of flexible electronic paper vary in specification due to different implementation techniques by different companies.

The flexible electronic paper display technology co-developed by Arizona State University and HP employs a manufacturing process developed by HP Labs called Self-Aligned Imprint Lithography (SAIL).

The flexible electronic paper display announced by AUO is unique as it is the only solar powered variant. A separate rechargeable battery is also attached when solar charging is unavailable.

Many of the e-paper based flexible displays are based on OLED technology and its variants. Though this technology is relatively new in comparison with e-paper based flexible displays, implementation of OLED flexible displays saw considerable growth in the last few years.

In May 2011, Human Media Lab at Queen"s University in Canada introduced PaperPhone, the first flexible smartphone, in partnership with the Arizona State University Flexible Display Center.

At CES 2013, Samsung showcased the two handsets which incorporates AMOLED flexible display technology during its keynote presentation, the Youm and an unnamed Windows Phone 8 prototype device.Galaxy Note Edge,Samsung Galaxy S series devices.

LG Electronics and Samsung Electronics both introduced curved OLED televisions with a curved display at CES 2013 hours apart from each other.The Verge noted the subtle curve on 55" Samsung OLED TV allowed it to have a "more panoramic, more immersive viewing experience, and actually improves viewing angles from the side."

Crawford, Gregory P., ed. (2005). Flexible flat panel displays (Reprinted with corrections. ed.). Chichester, West Sussex, England: John Wiley & Sons. p. 2. ISBN 978-0470870488.

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Lahey, Byron; Girouard, Audrey; Burleson, Winslow and Vertegaal, Roel (May 2011). PaperPhone: Understanding the Use of Bend Gestures in Mobile Devices with Flexible Electronic Paper Displays, Proceedings of the SIGCHI Conference on Human Factors in Computing Systems, Pages 1303–1312.

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