The History of LCD Displays and What the Future Holds

06 Aug.,2024

 

The History of LCD Displays and What the Future Holds

Here at Phoenix Display, we talk about LCD displays every day. With LCDs being such a big part of our daily lives, we thought it would be useful to explore the history of this important technology and where we see it going in the future.

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LCD Display History

First, let&#;s explore the history of LCD displays across different time periods.

s. Surprisingly, LCD technology dates back to the late 19th century. In , liquid crystal material was discovered in Austria by chemist Friedrich Reinitzer, which was about a decade before the cathode-ray tube (CRT) was invented.

s. Fast forward nearly 100 years and we have the first industry applications of liquid crystals. In , Hoffman-LaRoche filed for a patent in Switzerland for the twisted nematic (TN) field effect in liquid crystals. The company then licensed the technology to the Swiss manufacturer Brown, Boveri & Cie (BBC), which produced TN displays for wristwatches and other applications.

In , Sharp Corporation made use of LCD displays in calculators. Shortly after, the company followed BBC&#;s lead and mass produced TN LCD displays for watches in .

s. After wristwatches came televisions (TVs), with the first color LCD TVs being developed as handheld TVs in Japan. In , Seiko Epson released the first LCD TV, the Epson TV Watch, a wristwatch equipped with a small active-matrix LCD TV.

Just a few years later, in , Sharp announced a 14-inch, active-matrix, full-color, full-motion TFT LCD, which led to Japan launching the LCD industry. This industry developed large-size LCDs, including TFT computer monitors and larger LCD TVs.

s. The 90s gave way to technology acceleration in the LCD space. Through multiple breakthroughs, researchers and inventors were able to improve contrast and viewing angles, as well as bring costs down.

s. After 30+ years of competition, LCD technology surpassed longstanding CRTs. Namely, in , LCD TVs could claim better image quality than CRT-based TVs. Subsequently, in the fourth quarter of , worldwide sales of LCD TVs were higher than that of CRT TVs for the first time ever.

How Do LCD Displays Work?

Next, let&#;s take a brief look at how the technology works. Essentially, the LCD glass is just a light valve whose sole purpose is to either block light or allow light to go through it. We go into greater details in our post, &#;The Anatomy of LCD Displays,&#; but here&#;s the gist:

It accomplishes this simple task through the liquid crystal fluid, which is a fluid that&#;s rotated in a steady natural state between two pieces of glass. This rotation, when combined with front and rear polarizers, allows the light to be either transmitted through the glass or blocked. This light blocking state is changed when a voltage is applied to LC fluid which stops the light&#;s rotation.

What&#;s Happening with LCD Displays Over the Next 10 Years?

Finally, let&#;s look at the LCD display landscape in the near future. There&#;s three big areas that are being explored with LCD displays: Flexible displays, 3D displays, and reel-to-reel manufacturing.

Flexible Displays. Even now, you&#;re probably hearing buzz about flexible displays, which are bendable displays that are virtually shatterproof and unbreakable.

Development has been moving forward with these displays in both military and industry. Funding by the military makes sense given that flexible displays won&#;t break like traditional displays, providing for numerous field applications that require a more durable display.

In addition, there are plenty of industrial applications that would benefit from flexible displays, such as products that could use displays that wrap around objects.

3D Displays. With 3D being such a popular technology, it&#;s no surprise there&#;s activity in this space. These displays are capable of conveying depth perception to viewers, which provides for a more realistic user experience.

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Specifically, 3D displays with passive glasses (or no glasses) remove the requirement for syncing up with more expensive, active, shutter-based glasses. Naturally, this will lead to cost savings.

Reel-to-Reel Manufacturing. Current manufacturing processes only allow for building one glass panel at a time. Even with great efficiencies, this process is limiting.

In contrast, reel-to-reel manufacturing enables the continuous building of glass panels. This will represent a dramatic reduction in costs, which can be passed along to the customer and allow for more competitive pricing.

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Liquid crystal display (LCD)

liquid crystal display (LCD) , electronic display device that operates by applying a varying electric voltage to a layer of liquid crystal , thereby inducing changes in its optical properties. LCDs are commonly used for portable electronic games, as viewfinders for digital cameras and camcorders, in video projection systems, for electronic billboards, as monitors for computers, and in flat-panel televisions.

The optical properties of liquid crystals depend on the direction light travels through a layer of the material. An electric field (induced by a small electric voltage) can change the orientation of molecules in a layer of liquid crystal and thus affect its optical properties. Such a process is termed an electro-optical effect, and it forms the basis for LCDs. For nematic LCDs, the change in optical properties results from orienting the molecular axes either along or perpendicular to the applied electric field, the preferred direction being determined by the details of the molecule&#;s chemical structure. Liquid crystal materials that align either parallel or perpendicular to an applied field can be selected to suit particular applications. The small electric voltages necessary to orient liquid crystal molecules have been a key feature of the commercial success of LCDs; other display technologies have rarely matched their low power consumption .

Liquid crystals are materials with a structure that is intermediate between that of liquids and crystalline solids. As in liquids, the molecules of a liquid crystal can flow past one another. As in solid crystals, however, they arrange themselves in recognizably ordered patterns. In common with solid crystals, liquid crystals can exhibit polymorphism; i.e., they can take on different structural patterns, each with unique properties. LCDs utilize either nematic or smectic liquid crystals. The molecules of nematic liquid crystals align themselves with their axes in parallel, as shown in the figure. Smectic liquid crystals, on the other hand, arrange themselves in layered sheets; within different smectic phases, as shown in the figure, the molecules may take on different alignments relative to the plane of the sheets. (For further details on the physics of liquid crystalline matter, see the article liquid crystal .)

Twisted nematic displays

The first LCDs became commercially available in the late s and were based on a light-scattering effect known as the dynamic scattering mode. These displays were used in many watches and pocket calculators because of their low power consumption and portability. However, problems connected with their readability and the limited lifetime of their liquid crystal materials led to the development during the s of twisted nematic (TN) displays, variants of which are now available in computer monitors and flat-panel televisions.

twisted nematic cell

In the &#;off&#; state, in the absence of an electric field, the assembly is transparent to light. In the &#;on&#; state, an applied field destroys the twist of the nematic, rendering the assembly opaque.

A TN cell, as shown in the figure, consists of upper and lower substrate plates separated by a narrow gap (typically 5&#;10 micrometres; 1 micrometre = 10&#;6 metre) filled with a layer of liquid crystal. The substrate plates are normally transparent glass and carry patterned electrically conducting transparent coatings of indium tin oxide. The electrode layers are coated with a thin aligning layer of a polymer that causes the liquid crystal molecules in contact with them to align approximately parallel to the surface. In most currently manufactured displays, the alignment layers consist of a layer of polymer a few tens of nanometres thick (1 nanometre = 10&#;9 metre) that has been rubbed with a cloth in only one direction. In assembling the cell, the top and bottom substrate plates are arranged so that the alignment directions are perpendicular to each other. The whole assembly is then contained between a pair of sheet polarizers, which also have their light-absorption axes perpendicular to each other. In the absence of any voltage, the perpendicular alignment layers cause the liquid crystal to adopt a twisted configuration from one plate to the other. With no liquid crystal present, light passing in either direction through the cell would be absorbed because of the crossed polarizers, and the cell would appear to be dark. In the presence of a liquid crystal layer, however, the cell appears to be transparent because the optics of the twisted liquid crystal match the crossed arrangement of the polarizers. Application of three to five volts across the liquid crystal destroys the twisted state and causes the molecules to orient perpendicular to the substrate plates, giving a dark appearance to the cell, as shown in the diagram. For simple displays, the liquid crystal cell is operated in a reflective mode, with a diffuse reflector placed behind the display, and the activated parts of the electrode pattern appear as black images on a gray background provided by the diffuse reflector. By patterning the electrodes in segments or as an array of small squares, it is possible to display alphanumeric characters and very low-resolution images&#;for example, in digital watches or calculators.

More-complex images can be displayed using a technique known as passive-matrix addressing (described below). However, even with this technique, 90° TN displays can produce images consisting of only about 20 rows of picture elements, known as pixels.

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