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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.

A wide variety of flexible lcd display options are available to you, such as advertising publish, welcome display and shopping mall.You can also choose from video wall, digital poster and touch screen flexible lcd display,As well as from app control, ip67 waterproof, and 3g. And whether flexible lcd display is 1 year, 2 years, or {3}.

These thin flexible video screen have protective coating technology suitable for any weather and environment and are scalable to suit any function, size or venue. Choose from a range of thin flexible video screen available as lobby displays and way-finding systems, which optimize your retail promotions in style. The thin flexible video screen are versatile enough to integrate any product-type messaging for both single screen and enterprise-wide solutions.

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Flexible displays open up new dimension of design opportunities that aren’t possible with rigid glass-based displays. Nowadays, users have come to expect touch capability from almost any display-enabled device, but, many devices still need certain buttons or knobs – for example in cars. This becomes a limitation when using rigid glass displays - designers need to allow for additional space for knobs or buttons outside the display area. This can waste space, compromise aesthetics and result in a bulky non-optimised design.

Recently, some display makers have introduced glass displays with through-holes for the camera in smartphone screens. For example, Tianma has recently announced a 6.4” LCD with a through-hole that will be used in Huawei’s nova 4 device. It becomes more challenging and more expensive if the holes or the displays are larger, or if there are multiple holes required, when the displays are made from glass

In order to make displays flexible, the transistor backplane technology used needs to be flexible. This is currently made possible using conventional silicon technology or metal oxides on bespoke polyimide substrates. Flexible displays need to be mounted onto glass in order to keep them flat during fabrication. At the end of the process the flexible displays need to be demounted from the glass carrier by using a laser de-bonding process. Holes can be cut through the displays before or after the de-bonding process. If the demounting process is aggressive, like in the case of laser de-bonding for the polyimide-based displays, it can generate unwanted stresses which will cause the edges of the holes to be concentrated stress relief areas and hence impact yield and cost.

FlexEnable has developed a different approach for flexible displays. By using low temperature processing of organic thin-film transistors (OTFTs) on low cost plastics like triacetyl cellulose (TAC), no laser de-bonding processes are required. Instead a mild heat or UV treatment is used to separate the flexible displays from the glass. Holes through the displays are laser profiled while the displays are still mounted onto the glass. Unlike polyimide-based displays, OTFT displays have a simple high yielding demounting process.

As the landscape for flexible displays evolves with new use cases, the ability to cut holes through the displays unlocks even more design freedom and enables bolder product designs to meet growing consumer expectations.

Being completely made of plastic, Lectum® displays are much more rugged than standard glass-based EPDs. They are also thinner and lighter per square inch than conventional EPDs and are inherently low-power, which is vital in today’s increasingly mobile world.

Among the various improvements that smartphones and tablets have received over the last decade, flexible displays are undoubtedly one of the most interesting propositions and one with a huge potential to change the market. The technology is still relatively new, despite several companies exploring the tech for more than a decade.

After seeing several new devices successfully integrate flexible displays with varying levels of success, it"s clear that this tech is here to stay. The only question right now is how long it will take for flexible displays to become commonplace. Let"s take a look at how modern flexible displays work and future considerations for this corner of the market.

Smartphone displays are traditionally rigid due to the glass layer used in their production. However, modern OLED-based designs have successfully removed the need for that, instead implementing the screen in a very thin layer, to the point where it becomes flexible. The screen is then covered with a thin plastic layer, which is unfortunately susceptible to scratches.

Modern solutions also implement glass protection. The Galaxy Z Flip was a small revolution in this regard, utilizing a thin layer of glass underneath the plastic cover. While the main surface was still finished with plastic, the underlying glass was still a major improvement over previous designs on the market.

In some cases, flexible displays are just an illusion. Some devices feature two or more displays lined up next to each other, with special emphasis placed on removing the border between them. These devices are usually more versatile in terms of the kinds of upper layers they support, in some cases including a full glass cover.

Flexible displays have been around for a decade now. Initial designs were rather underwhelming—but some of them ended up being repurposed into other devices. For example, the Galaxy Note Edge"s curved screen actually started as a prototype for a flexible display device.

The Galaxy Z Flip 3 is a notable example of a device that incorporates a flexible display, and some claimed that it should set some new trends on the market. Unfortunately, other manufacturers haven"t tried to follow the trend, so it remains to be seen whether the idea has any true potential. The device sold well enough, which is a good sign.

And in some cases, flexible displays were used to achieve a different effect. The iPhone X, which started the trend of screens with curved corners, actually used a flexible display to accomplish that without sacrificing any real estate around the bezels.

Flexible displays remain relatively expensive compared to their regular counterparts and often sacrifice visual quality. This is especially noticeable when the screen is folded at a particular angle. At the same time, flexible screens tend to have a more limited lifetime compared to traditional ones.

For most user"s needs, current designs should be able to last a very long time. But this is still a point that needs to be addressed by most manufacturers, especially in the context of the higher prices attached to flexible display devices.

It"s also important to note that flexible displays have huge potential outside of the smartphone market. Other devices can utilize them to improve their usability. Furthermore, with wearable gadgets increasing in popularity, new gadgets coming out in the future are likely going to take advantage of this technology.

Smartwatches are a good candidate for flexible display technology. Their designers already go to great lengths to make their displays as compact as possible, and flexible displays offer some direct advantages in this regard. They tend to be thinner than traditional displays, which makes them a good fit for devices of this kind.

Then there are medical devices and other specialized use cases. Even if flexible displays don"t immediately take off, they will find a place in other areas. It will be interesting to see what kinds of changes they facilitate in other markets.

Gaming is also shaping up to be a field where these devices could have a viable place. Between virtual reality and the new features being introduced in modern consoles and their controllers, we might see some approaches that integrate flexible displays.

With all that said, the main question remains—will this eventually become a common trend on the market as a whole? As we mentioned above, there are specialized cases where bendable or flexible displays have potential.

Backplanes are the most essential component of electronics because they can connect in parallel with each other and control the electrical signals of devices. As opposed to the passive-matrix form, the active-matrix backplane allows selective access to each component with a rapid response while maintaining a high-circuit density by sharing electrode lines. Despite many advantages of active-matrix backplanes, the realization of deformable active-matrix backplanes with reliable operation is very challenging. This is because three electrodes (gate, source, drain) of each component are connected to different word and bit lines and grounds, and the failure of only one single component can lead to the failure of the whole backplane. Therefore, it is important to minimize stress during deformations of thin-film transistor (TFT)-based electronics. The deformability of backplanes is commonly obtained by modifying device materials and structures to accommodate most of the strains induced by bending, folding, and even stretching. These modifications can be classified into two approaches: one uses intrinsically flexible materials (e.g., ultrathin or elastomeric materials) and the other uses an engineered substrate.

The most basic method of obtaining flexibility or bendability is the adoption of ultrathin materials as the TFT backplane components.2a, b. In addition, no fracture was found on the oxide semiconductor TFT regions due to the thin thickness of the backplane (~2 µm) and the improved flexibility of the TFT regions. Javey and coworkers have demonstrated a flexible display that is composed of a flexible carbon nanotube (CNT)-based backplane and flexible organic light-emitting diode (OLED) pixels as depicted in Fig. 2c, d (ref. 3). The flexible display was fabricated on a 24-µm-thick PI film, and the total thickness of the devices (excluding the substrate) was <2 µm. Therefore, the flexible backplane showed stable electrical characteristics even during the bending states (where the bending radius was 4.2 mm), and the OLED pixels also performed with negligible degradation from the deformations (where the bending radius was 4.7 mm). Consequently, this fabricated display also demonstrated flexibility because of the deformability of the devices.

Flexible backplane for display fabricated by a thin-film process. a Photo (left) of the TFT array sample made by graphene–AuNT hybrid electrodes on a transparent polyimide substrate. Scale bar: 1 cm. A schematic diagram (right) of the TFT layout. b Photos of the TFT arrays transferred onto: a leaf, eyeglasses, and the skin of human hand. All scale bars: 1 cm. a–b Reproduced with permission from ref. 8. Copyright 2014, American Chemical Society. c Photo (left), optical micrograph (middle), and scanning electron micrographs (right) of flexible backplane. d Photos of operating flexible display combined with backplane and OLED pixels. c–d Reproduced with permission from ref. 3. Copyright 2013, Nature Publishing Group

Many studies have demonstrated flexible electronics with various methodologies. However, in the case of the aforementioned methods, mechanical stresses continue to be induced on the brittle electronic materials, even though the stresses are relieved. Therefore, the mechanical stresses generate fatigue on the electronics during repetitive or constant deformations, and the accumulated fatigue causes severe problems that deteriorate the performance and reliability of flexible TFT backplanes. Consequently, reducing fatigue becomes a key challenge to realizing highly flexible and stable backplanes or electronics. The typical method of reducing mechanical fatigue on the TFT backplane is the adoption of device islands-interconnect designs. These designs are based on engineered substrates that are composed of materials with different values of elastic modulus.3a.1 summarizes the recent advances in stretchable interconnect technology.3b). The stretchable conductors showed high stretchability at over 200% strain as plotted in Fig. 3c. Based on these systems, the stretchable backplane also demonstrated superb stretchability up to the strain of 110% (Fig. 3d). In addition, Kim et al. have also demonstrated a reversibly foldable TFT backplane based on the oxide semiconductor (indium oxide (In2O3)), which shows high performance and is used in the conventional backplane.3e). The designed stretchable conductors exhibited stretchability up to the strain of 100% and also exhibited stability against cyclic tests (10,000 times with the 80% strain), as shown in Fig. 3f. Because of these superior interconnects and engineered substrates, the oxide semiconductor TFT backplane also showed high stability during the folding states without any degradation (Fig. 3g). In addition, Park and his team have also studied stretchable TFT backplanes based on these two systems Fig. 3h. Their TFT backplanes also provided reproducible performances up to the strain of 25%, as shown in Fig. 3i, and showed high stability against fatigue (5000 times with the 20% strain), as shown in Fig. 3j. The reliability of the stretchable TFT backplane is affected by the strain isolation effect of engineered substrates and the high stability of stretchable interconnects (Au film on AgNWs-embedded elastomer).

Device islands-interconnect design for highly flexible TFT backplane. a Simulation of strain manipulation at the top surface of the engineered substrate. Reproduced with permission from ref. 9. Copyright 2013, American Institute of Physics. b Schematic illustrations of OTFT backplane on engineered substrate. c Conductivity dependence on tensile strain in printed elastic conductors with and without surfactant. d Transfer characteristics of OTFT according to the tensile strain. b–d Reproduced with permission from ref. 12. Copyright 2015, Nature Publishing Group. e Schematic images (top) and scanning electron micrographs (bottom) of stretchable conductor (Au film on AgNWs-embedded elastomer) before and after stretching. Scale bars: 5 μm. f Resistance dependence on tensile strain (left) and cyclic numbers (right) of the stretchable conductor (Au film on AgNWs-embedded elastomer). g Images (top) and output characteristics (bottom) of foldable TFT backplane on engineered substrate before and after folding. Scale bars: 5 mm (black) and 100 μm (red). e–g Reproduced with permission from ref. 13. Copyright 2016, Royal Society of Chemistry. h Illustration and photograph (inset) of stretchable TFT backplane on engineered substrate. i Electrical properties of device in h according to the mechanical strain (up to a strain of 25%). j Electrical properties of device in h according to the number of cycles

The research activities for developing TSP technologies at UNIST have been devoted mainly to exploring new materials, device structures, and device fabrication processes for multi-functional flexible and stretchable TSPs. One noticeable achievement is the development of the highly flexible capacitive TSP with AgNW diamond-pattern electrodes and transparent bridge structures formed on a polycarbonate film.4 shows the structure and touch-sensing capability of the fabricated TSP. As shown in the Fig. 4, the bridge structure is composed of an epoxy polymer (SU-8)-based bridge insulator and an Al-doped zinc oxide (AZO) bridge electrode. In order to secure the stable and robust connection between the AZO bridge electrode and the AgNW diamond-pattern electrodes over the bridge insulator, the side-wall slope of the bridge insulator is made as low as possible with our unique photolithography process, in which the exposure time is extended beyond the optimized value for forming vertical side-walls. With the extended exposure time, the lower part of the SU-8 layer immediately adjacent to the direct exposure region can be sufficiently exposed to the stray ultraviolet (UV) light scattered from the substrate, leading to the formation of a bridge insulator with a low side-wall slope. The fabricated TSP sample was found to be highly flexible and transparent and also showed good touch-sensing performance. The measured capacitance changes by ~22.7% with the finger touch.

0 represents the width of the AgNW electrode when the sensor is relaxed). Also, the upper PDMS insulator sandwiched between the top and middle electrodes will become thinner than the lower one sandwiched between the middle and bottom electrodes. Hence, the capacitance of the upper capacitor (C

Based on their superb operational performances and functionalities, the flexible and stretchable TSP devices developed at UNIST, including the two introduced above, are expected to significantly enrich the information communicated between humans and machines. Thus, it is quite probable that these devices will be used extensively in various future information technology applications.

Flexible light sources are important parts in flexible display applications because they determine long-term stability and commercial value of practical flexible displays under continuous mechanical stress. Thus, flexible light sources should have sufficient light-emission efficiency and mechanical stability. Generally, OLEDs have been mostly spotlighted candidates for flexible light sources because OLEDs consisted of organic materials and they have outstanding mechanical flexibility compared with inorganic LEDs.

Following constituent materials of flexible OLEDs, there are four major research issues (substrates, electrodes, light-emissive materials, and encapsulation) to be perfectly developed for practical future applications; flexible substrates, electrodes, light-emissive materials, and encapsulation. Here, we briefly introduce technical research issues with four sections and suggest future research directions of flexible OLEDs.

Almost all of the macroscopic flexibility of flexible OLEDs comes from substrates. The important properties of flexible substrates are mechanical flexibility, thermal stability, optical transparency, and gas barrier properties.

Highly conductive poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS) have been investigated for flexible electrodes with highly smooth surface, optical transparency, easy processes, and enhanced electrical conductivity up to 4380 S/cm by doping with polar solvents or concentrated sulfuric acid.6. In addition, hybrid flexible electrodes composed of PEDOT:PSS and AgNWs were said to be mechanically durable and robust OLED characteristics were said to be obtained.

a Schematic illustration of thermal annealing and LPEB irradiation of AgNWs. b Schematic illustration of fabrication process for AgNW/PEDOT:PSS composite electrode and the PLED structure, and photograph of light-emitting flexible PLEDs with AgNW/PEDOT:PSS electrode

Most components of flexible OLEDs are organic materials that can easily react with oxygen and moisture because plastic substrates and other components have low gas barriers. The water vapor transmission rate (WVTR) is strongly related to the long-term stability and feasibility of practical flexible OLEDs. OLEDs generally require a WVTR of approximately 10−6 g/m2∙per day, which is a very low value compared to inorganic LEDs.−3 g/m2∙day, as shown in Fig. 8.

For next-generation displays, flexible and light-weight OLEDs are an appropriate candidate because of their excellent light emission, and mechanical flexibility. Currently available components of flexible OLEDs including substrates, electrodes, emissive materials and encapsulation layers, are still insufficient to achieve practical flexible OLEDs with stable performance under mechanical deformation. Consequently, achieving reliable components of flexible OLEDs such as (1) flexible substrates and encapsulation layers with good barrier properties, (2) transparent electrodes that are mechanically robust under deformation and have low sheet resistance, and (3) flexible materials that emit light efficiently, remains to be solved for commercial applications.

Recently, flexible display devices have attracted widespread attention as an alternative to rigid devices because of their portability and comfort for long time wearing. For the relevant applications, when the devices undergo mechanical deformations such as bending and stretching, the thicknesses of the constituent materials usually decreases and all layers suffer a tensile stress at the outside of each layer.

Nanoindentation was developed to measure the mechanical properties of small-volume and thin-film materials. The outstanding merit of nanoindentation is that it has a simpler procedure for small-scale sample preparation compared with other mechanical tests. During indentation with a sharp-tipped indenter on the sample surface, as shown in Fig. 9, the force and indentation depth are continuously measured over an indentation depth ranging from a few tens of nanometers to a few micrometers. The hardness and elastic modulus can be calculated from the force-indentation depth data using the Oliver-Pharr method

As mentioned above, nanoindentation can measure small-scale materials such as thin-films, nano-particles, etc. However, when the sample thickness is below approximately 100 nm, it is difficult to use nanoindentation because of the “1/10 rule”, which states that the maximum indentation depth is approximately 1/10 of the sample thickness, to exclude the substrate adversely influencing the experimental results. Lee et al.10. The mechanical properties of this film were calculated from force-penetration depth data based on the following non-linear elastic response model:

Flexible display devices contain many laminated structures composed of sub-micrometer-scale thin films. At UNIST, we evaluated the mechanical properties of one of these components using modified hole-nanoindentation. PDY-132 (Merck, Germany, commercially sold as “Super Yellow”) is a ‘‘high-performance polymer’’ that emits yellow light. In our evaluation, PDY-132 was spin-coated on a clean glass substrate. The sacrificial layer was selectively dissolved to fabricate free-standing films with the same dimensions as the actual devices. We fabricated hole-patterned Si wafers using the deep reactive ion etching method. The patterned hole size was proportional to each film thickness, so that the diameter of a hole was less than 1% of the film thickness.11. The elastic modulus of the hole-indentation was found to be 4.89 GPa, and its fracture strength was 1.19 GPa.

Uchic et al.12. Tensile testing is the most fundamental method of evaluating a material’s inherent mechanical properties, such as yield strength, strain-hardening exponent, ultimate tensile strength, etc. As mentioned above, in-situ testing enables precise observations of sample deformations in real time, with simultaneous imaging during testing. Various indenters are also expected to enable stretching and bending tests of constituent materials in flexible display devices.

Flexible display devices contain many organic materials, such as polymer films, active materials, and electrodes. However, mechanical tests of organic materials in high vacuum conditions in SEM and transmission electron microscopy are limiting in that organic materials are (in real environments) highly affected by surrounding environmental conditions such as humidity and temperature; it is important to measure mechanical properties in actual operating environments. A nano-UTM can be used to control environmental conditions using a controlled humidity chamber and heating block because the machine is based on an optical microscope, as shown in Fig. 13. Images of gauge sections during tensile tests are observed by a charge-coupled device camera in real time, and strain is analyzed from the images based on digital image correlation. Constituent materials in flexible display devices are macroscopically visible and their thicknesses are generally in the nanometer-scale range. PEDOT:PSS is widely used for organic transparent conducting electrodes, and PEDOT:PSS thin films are fabricated by natural drying after drop casting on a substrate. A tensile sample was fabricated by a mechanical press, and the gauge length and gauge width were 4 and 1 mm, respectively, as in the standard ASTM E8 test. We performed tensile tests of PEDOT:PSS in three different humidity conditions by nano-UTM, and the results are summarized in Fig. 13. The yield strengths of the samples tested in the lowest humidity environment were greater than those of other samples, and the fracture strain decreased as humidity increased.

In recent years, fingerprint mutual capacitive TSPs with flexible displays fabricated from flexible plastic materials have attracted much attention because of the development of transparent fingerprint sensors embedded in flexible displays that are also thin and impact-resistant. As security protections for electronic devices such as smart phones become increasingly important, a fingerprint sensor has been integrated on the device’s home button because the fingerprint sensor is not transparent. However, a mutual capacitive transparent fingerprint TSP must be developed on the display itself because a wearable device does not have a home button, and the screen sizes of smart devices must otherwise be enlarged.

To make a flexible TSP, a flexible and transparent material must be used for the TSP electrode. However, variation in load becomes a concern when the flexible electrodes of the fingerprint TSP are bent or stretched, which can interfere with capturing the fingerprint image. Because the capacitance difference of the mutual capacitive fingerprint TSP from the ridge to the valley is several hundred atto-farads, the effect of the load variation due to a bent or stretched TSP will be very critical.

Both the flexible fingerprint TSP and post-processing are required to capture the fingerprint image in the fingerprint TSP on the flexible display. A readout IC for the flexible fingerprint TSP is required to distinguish the atto-farad capacitance difference in the fingerprint TSP noise environment on the flexible display. Post-processing is also necessary to compensate for the load variation due to the bent or stretched display.

Figure 14 shows a simplified structural model of the human skin and a fingerprint TSP. The human skin is composed of the dermis layer and the epidermis layer, which includes the valleys and ridges of the fingerprint. The epidermis layer consists of dry dead skin cells, which have low electrical conductivity; this region behaves as a dielectric. The dermis layer consists of live cells, which are moist and electrically conductive. The mutual capacitive touch screen sensor measures the difference in permittivity between the ridge surface skin and the air in the valleys. A fingerprint consists of many ridges and valleys on the surface of the finger. The width of the ridges varies in the range of approximately 0.5–0.7 μm, and the widths of the valleys are approximately 0.15 μm. The depth of the valley varies in the vicinity of 150 μm. If the depth of the valley is lower than 150 μm, the capacitor difference due to the valley and ridge is also very small.

When the thickness of the covered glass of the flexible display is almost 0.2–0.3 mm, the mutual capacitance difference from the valley to the ridge is almost 50–150 atto-farad. As the thickness of the display panel increases, the mutual capacitance difference is reduced. The thickness of the rigid glass is larger than that of the flexible display panel, which induces a capacitance difference between the valley and the ridge of only several atto-farad.

A proposed high voltage transmitter and the low-noise, low-capacitance sensing circuits for the fingerprint touch screen panel. Reproduced with permission from ref. 70. Copyright 2014, IEEE

A low-noise, low-offset, and fast-response receiver is required to acquire a fingerprint image in the mutual capacitive fingerprint TSP on the flexible display. In addition, the post-processing is also required to compensate for the load variation issues that occur because of the flexible TSP’s unique characteristics. A readout IC with high accuracy and a fast response and an effective algorithm for cancelling the offset due to the load variation are both required to achieve an effective fingerprint TSP on the flexible display.

It is also important to understand how our visual perception operates to better inform our visual display designs. Related concepts include the just noticeable difference (JND), horopter, and depth perception. For example, JND values for display curvature can be used to determine a specific display curvature within the JND range, within which our perception is regarded equal. The horopter concept contributes significantly to the advantages offered by curved displays in comparison with flat displays. Horopter is “the locus of points in space which project images onto corresponding points in each retina”.

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.

Nokia introduced the Kinetic concept phone at Nokia World 2011 in London.Engadget described interactions such as "[when] bend the screen towards yourself, [the device] acts as a selection function, or zooms in on any pictures you"re viewing."

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.

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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.

Gomes, A., Nesbitt, A., and Vertegaal, R. (2013) MorePhone: A Study Of Actuated Shape Deformations for Flexible Thin-Film Smartphone Notifications. In Proceedings of ACM CHI’13 Conference on Human Factors in Computing. ACM Press, 2013, pp. 583–592.

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New York, United States, July 19, 2022 (GLOBE NEWSWIRE) -- The global flexible display market had a market share of USD 13.34 billion in 2019, according to the new report of Straits Research. It is predicted to grow at a CAGR of 34.83% from 2022 to 2030. The global flexible display market is expected to grow owing to the rising innovations in consumer electronics and increased demand for a high-quality picture. Integrating smart sensors into residential devices has lengthened the replacement cycle for new consumer electronics. Displays are increasingly being used to control and communicate with devices.

The growing trend of smart homes and buildings and the increasing demand for connected technologies are some of the major factors driving the adoption of connected and innovative solutions across the consumer electronics sector. Effective data storage is becoming critical, with so many viewers consuming media from OTT platforms such as Netflix, Amazon, and others. Thus, the demand for TVs is expected to boost the flexible displays market.

Further, the growing demand for greater picture quality bolsters the demand for flexible displays. The number of 4K televisions sold has increased exponentially in recent years. According to JEITA, the number of 4K TVs shipped in Japan in 2020 will be 3.05 million, up from 2.58 million the previous year. The increase in demand is expected to be driven by the change in resolution and quality of the contents.

Lastly, more exciting and demanding technology, such as virtual reality and 4K displays, is now available. As a result, PC gamers are expected to upgrade their equipment, which is one of the factors driving sales of gaming-specific PCs and their accessories, such as gaming screens. As a result, increased need for picture quality has increased the demand for flexible displays. Report MetricDetails

Due to the global shutdown, production of flexible displays fell precipitously in 2020 due to the global supply chain disruption. COVID-19 had an impact on the operations of not only flexible display manufacturers but also their suppliers and distributors.

In the short term, the failure of export shipments and poor domestic semiconductor demand compared to pre-COVID-19 levels are expected to impact negatively and slightly stagnant demand for semiconductor devices, affecting the flexible display market.

As a result of the ongoing COVID-19 outbreak, several major economies have been placed on lockdown. Sales of electronic products have been hampered, and supply networks have been disrupted. Furthermore, many economies are losing a significant amount of revenue due to manufacturing plant closures. As a result, the general scenario has hampered the demand for flexible displays in 2020.

Growing use of flexible displays in the consumer electronics industry for smartphones, wearable devices, laptops, and its peripherals is expected to boost the category.

Due to their expanding use in flexible displays, wearable electronics, smart cards, and various other applications, flexible batteries are growing in popularity. A flexible display is also a rapidly growing technology, with applications of flexible display in areas such as media, aircraft, and transportation. Research on flexible display predicts increasing usage of this display technology in medical display systems.

The surge in demand for flexible display technology for a variety of applications such as digital signage, smartphones and tablets, and smart wearable devices is likely to drive the global flexible display market. The growing prominence of quantum dot (QD) display technology presents manufacturers with new revenue prospects and is likely to emerge as one of the important types of display technology.

Key Findings of Market ReportOver the next few years, the market is expected to be driven by the increasing use of flexible displays in different industries such as consumer electronics, automotive and transportation, media and entertainment, and aviation and military. The future of phone design with flexible display holds promise in the development of mobile devices and smart displays is also expected to propel the flexible display market during the forecast timeline. In addition to that, the global market has been propelled by increasing expenditures on the development of sophisticated displays.

Due to the surge in usage for curved displays from the consumer electronics sector for the manufacturing of TVs and smartphones, the curved display category is likely to hold a significant proportion of the market during the forecast timeframe. A flexible display is basically the same as any other display, except that it is built on a flexible substrate.

OLED is a rapidly growing category of the global flexible electronics market in terms of technology. Due to the glass layer utilized in display manufacture, smartphone screens are traditionally inflexible. However, the newest OLED-based technology has eliminated the requirement for it, substituting a thin film of flexible glass with a thin layer of OLED-based technology. The OLED display, which is constructed of organic components that generate light when power is transmitted between them, is now prominent due to its versatility.

Global Flexible Display Market: Growth DriversAutomakers are concentrating on integrating flexible screens into car interiors. Over the next several years, a substantially bigger section of a car"s interior surfaces is likely to become interactive, and the amount of space given to displays in vehicle interiors is already fast expanding.

Based on value, the Asia Pacific region held 34% of the global flexible display market in 2021. The high usage of flexible displays in consumer electronics, which represented a substantial chunk of overall consumption in Asia Pacific, was largely responsible for the considerable share. In Asia Pacific, China accounted for a sizable portion of the flexible display business.

Industrial Touchscreen Display Market- Industrial Touchscreen Display Market is anticipated to reach value of US$ 1,462.5 Mn by 2026, expanding at a significant growth rate of 6.5%.

Thin, flexible screens such as the one showcased by LG could allow the creation of newspapers that change daily, display video like a tablet computer, but that can still be rolled up and put in your pocket. These plastic electronic displays could also provide smartphones with shatterproof displays (good news for anyone who"s inadvertently tried drop-testing their phone onto the pavement) and lead to the next generation of flexible wearable technology.

But LG"s announcement is not the first time that flexible displays has been demonstrated at CES. We"ve seen similar technologies every year for some time now, and LG itself unveiled another prototype in a press release 18 months ago. Yet only a handful of products have come to market that feature flexible displays, and those have the displays mounted in a rigid holder, rather than free for the user to bend. So why is this technology taking so long to reach our homes?

Take a look at your computer screen through a magnifying glass and you"ll see the individual pixels, each made up of three subpixels – red, green, and blue light sources. Each of these subpixels is connected via a grid of wires that criss-cross the back of the display to another circuit called a display driver. This translates incoming video data into signals that turn each subpixel on and off.

How each pixel generates light varies depending on the technology used. Two of the most common seen today are liquid crystal displays (LCDs) and organic light emitting diodes (OLEDs). LCDs use a white light at the back of the display that passes through red, green and blue colour filters. Each subpixel uses a combination of liquid crystals and polarising filters that act like tiny shutters, either letting light through or blocking it.

Whatever technology is used, there are many individual components crammed into a relatively small space. Many smartphone displays contain more than three million subpixels, for example. Bending these components introduces strain, which can tear electrical connections and peel apart layers. Current displays use a rigid piece of glass, to keep the display safe from the mechanical strains of the outside world. Something that, by design, is not an option in flexible displays.

Organic semiconductors – the chemicals that directly produce light in OLED displays – have the additional problem of being highly sensitive to both water vapour and oxygen, gases that can pass relatively easily through thin plastic films. This can result in faded and dead pixels, leaving a less than desirable-looking result.

Finally, it"s not just flexible displays that need to be developed. The components needed to power and operate the display also need to be incorporated into any overall design, placing constraints on the kinds of shape and size currently achievable.

Scientists in Japan have demonstrated how to make electrical circuits on plastic thinner than the width of human hair in an attempt to reduce the impact of bending on circuit performance. And research into flexible batteries has started to become more prevalent, too.

Developing solutions to these problems is part of a broader area of active research, as the science and technology underlying flexible displays is also applicable to many other fields, such as biomedical devices and solar energy. While the challenges remain, the technology edges closer to the point where devices such as flexible displays will become ubiquitous in our everyday lives.

The world of electronics is constantly evolving, and innovative material technologies have facilitated a massive leap in the development of more compound hi-tech displays for mobile devices. Consequently, flexible displays are no more a marketing gimmick but a major and extremely imperative display technology innovation which holds enormous potential to deliver resolutions that are light, thin, and foldable.

As per the expert analysts at Technavio, the next five years are promising to bring advanced flexible display panels for smartphones to the global market. Subsequently, end-users of the smartphone will be able to fold, twist and roll them like paper, at their convenience.

While Samsung, LG, and many other top smartphone brands have been displaying prototype phones for years, it is only now that flexible screen phones are going commercial. When these brands talk about a flexible display technology, they are indeed speaking about the organic light-emitting diode (OLED) display panel precisely placed beneath the cover glass which is now made using plastic material rather than rigid glass.

There are several benefits to display that moves and bends. The latest flexible displays promise to be lighter and thinner as they have fewer layers than the LCDs we see on tablets and phones now. Additionally, flexible displays are more durable than today’s phone displays, thanks to the plastic materials used in producing a range of smart and flexible displays.

The mobile phones with flexible screens have driven several smartphone manufacturers to catch up in this fierce battle as they jostle to win market share with the groundbreaking products. In the recent times, Xiaomi and Vivo – the Chinese brands released their first smartphones with flexible active-matrix organic light-emitting diode (AMOLED) displays, while many other manufacturers have robust plans to develop their own foldable and dual-edge curved smartphone designs.

Above all, Apple is expected to unveil its latest iPhone equipped with flexible AMOLED display in the year end, which would dramatically drive up estimated demand for flexible display panels.

We are on the verge to experience the electrifying technology that will revolutionize the smartphone industry beyond the imagination. With a surge of engineers working hard to develop cutting-edge tech, flexible displays are absolutely a module to watch in the mobile space.

Founded by a Stanford PhD graduate, Royole has designed and is starting to mass-produce a super-thin flexible screen that could be used in everything from t-shirts to portable speakers.

Its new screen technology is coming on the market just in advance of the expected debut of the first foldable phones that will be built around similar technology.

It"s the stuff of science fiction, and plenty of tech trade shows — a screen so thin and flexible that it can be rolled up into a cylinder as small as a cigarette or hung on a wall like wallpaper.

The company, which is based in the San Francisco Bay Area, has come up with a way to make a full-color, high-resolution screen that is just 0.01 millimeters thick — thinner than a sheet of standard copy paper.

Royole just opened a new factory in China that is already mass producing the displays, and the company is working with partners to get them installed in everything from t-shirts to automobiles to smartphones.

Royole"s screens are based on OLED technology, in which the lighting elements are built into the display itself. Unlike the OLED screens that are in some higher-end televisions, which are typically placed on a rigid base like glass, the lighting elements in Royole"s screens are placed on a flexible plastic base, so they can bend or roll up.

"The cool thing here is that we"re not limited by the form factor of the surface," said Liu, who founded Royole with some friends from Stanford after graduating from there with a PhD in electrical engineering. "They could be anywhere."

Researchers have been trying to develop flexible screen technology since at least the early 1970s — first in the form of monochrome displays that were intended to replace printed pages, and then, much later, in the form of color ones that might replace the screens in TV or portable devices.

For much of the last decade, display makers including Samsung and LG have been showing off their flexible OLED screens and prototype of products made with them at trade shows.

Samsung"s Galaxy Round, a relatively obscure smartphone that came out that year, was one of the first gadgets that used a flexible screen way back in 2013. Because the display was placed behind a fixed plate of glass, so you couldn"t really tell that it was bendable. The only clue was that the front of the phone was concave.

Other smartphones since the Galaxy Round have also employed flexible displays, including the LG G Flex and the Edge versions of the Samsung Galaxy S and Galaxy Note lines. More recently, the screens have started to make their way into even mainstream devices. Apple"s iPhone X, for example, has a flexible display behind its famously notched screen.

Neither businesses nor consumers were ready for bendable or foldable gadgets when the first flexible displays started rolling off production lines five years ago, analysts said. Electronics makers generally hadn"t set up their supply chains to accommodate them or figured out how they might be able to take advantage of the screens" properties in new products. Apps hadn"t been written specifically for devices with bendable screens. And nobody had laid the groundwork for new kinds of flexible gadgets by marketing them to consumers.

Things may be different now. Next year, Samsung will reportedly introduce a phone with a foldable screen that"s built around its flexible display technology. Apple reportedly has a foldable phone in the works, too.

"You can"t make [phones] much bigger … and have them be carried by most consumers," Soneira said. "So you"ve got to move up to foldable, even rollable screens."

The release of foldable screen phones and other gadgets from major manufacturers will likely spur developers to start making apps designed specifically around those features. It"s also likely to inspire demand for other devices that take advantage of the properties of bendable screens.

Flexible screens will likely get their start by replacing other screens in devices we already recognize, including not just smartphones, but computer monitors and laptop computers, allowing manufacturers to make models that are slightly more innovative or resilient, said Ryan Martin, a principal analyst at ABI Research. But eventually, manufacturers are likely to get a lot more creative with them.

A flexible display "changes the realm of design as well as design thinking," Martin said. "You"re no longer confined to the four corners of a screen. You can make things more abstract."

At CES, the giant electronics trade show held in