full active lcd displays brands

Sharp NEC Display Solutions incorporates both Sharp and NEC brands of display products. Including desktop, 4K and 8K UHD large format, video wall, dvLED, collaboration and interactive products, Sharp/NEC offers the widest portfolio of displays available. Understanding that every market and environment has unique requirements, Sharp/NEC prides itself on being your partner, delivering customized solutions to match your needs.

Planar® CarbonLight™ VX Series is comprised of carbon fiber-framed indoor LED video wall and floor displays with exceptional on-camera visual properties and deployment versatility, available in 1.9 and 2.6mm pixel pitch (wall) and 2.6mm (floor).

From cinema content to motion-based digital art, Planar® Luxe MicroLED Displays offer a way to enrich distinctive spaces. HDR support and superior dynamic range create vibrant, high-resolution canvases for creative expression and entertainment. Leading-edge MicroLED technology, design adaptability and the slimmest profiles ensure they seamlessly integrate with architectural elements and complement interior décor.

From cinema content to motion-based digital art, Planar® Luxe Displays offer a way to enrich distinctive spaces. These professional-grade displays provide vibrant, high-resolution canvases for creative expression and entertainment. Leading-edge technology, design adaptability and the slimmest profiles ensure they seamlessly integrate with architectural elements and complement interior decor.

From cinema content to motion-based digital art, Planar® Luxe MicroLED Displays offer a way to enrich distinctive spaces. HDR support and superior dynamic range create vibrant, high-resolution canvases for creative expression and entertainment. Leading-edge MicroLED technology, design adaptability and the slimmest profiles ensure they seamlessly integrate with architectural elements and complement interior décor.

Planar® CarbonLight™ VX Series is comprised of carbon fiber-framed indoor LED video wall and floor displays with exceptional on-camera visual properties and deployment versatility, available in 1.9 and 2.6mm pixel pitch (wall) and 2.6mm (floor).

Carbon fiber-framed indoor LED video wall and floor displays with exceptional on-camera visual properties and deployment versatility for various installations including virtual production and extended reality.

a line of extreme and ultra-narrow bezel LCD displays that provides a video wall solution for demanding requirements of 24x7 mission-critical applications and high ambient light environments

Since 1983, Planar display solutions have benefitted countless organizations in every application. Planar displays are usually front and center, dutifully delivering the visual experiences and critical information customers need, with proven technology that is built to withstand the rigors of constant use.

This is another story just like those, except this one involves the very screen you’re probably looking at, especially if it’s based on LCD technology.

In the 1970s, a pair of engineers that worked for Westinghouse, T. Peter Brody and Fang-Chen Luo, came to develop the first active-matrix LCD screen. Brody, born in Hungary, had gained an interest in the fledgling technology of thin film transistors, an experimental technology that had come to be seen as a potential avenue for visually displaying content in a more compact form than a cathode-ray tube.

“It has been apparent for some time that a solid-state flat panel display is conceptually achievable,” the patent filing stated. “Efforts to utilize silicon technology to this end are limited by the size limitation problems of the silicon wafer, which negates achievement of large area displays.”

But it was the starting point of the technology that stuck. By the mid-1990s, active-matrix displays that relied on color became the norm in laptops, thanks to their combination of vivid color and thinness. But despite the concept coming from an American company’s R&D department and improved by other American R&D departments, nearly all panels were developed by Japanese manufacturers even at the beginning of their mainstream use cases.

In fact, Westinghouse’s efforts with the flat-panel LCD display ended way back in the 1970s, as did similar efforts at other large U.S. companies. “Both large corporations and venture capital-backed start-ups have quit the field, usually after hitting production difficulties,” authors Richard Florida and David Browdy wrote.

Mercury"s military-grade LCD modules improve operational safety, enhance end-user efficiency, and reduce complete lifecycle costs by customizing active matrix LCD characteristics to your unique application. Whether it is in the air, on the ground, under the sea, day or night, hot or cold, displays built with Mercury"s LCD modules illuminate mission-critical data, regardless of where you work.

Safety-certifiable up to DAL-A, rugged, and NVIS compatible, Mercury"s LCD modules operate in demanding environments and enhance user situational awareness.

The V-R44P is a rack mountable unit that offers four 4" high-resolution active matrix LCD panels. Each of the four 480 x 234 pixel screens has its own set of controls for color, tint, contrast, and brightness. Each panel has its own input with active loop-through feature, a 3 color tally system, and auto-recognition of NTSC or PAL formats. This unit is only 2U high, can be tilted up to 100 degrees while rack mounted, and is the smallest video monitoring system of its kind. All V-R Series models are constructed of steel and aluminum, and include a power supply.

There are, however, a number of European companies with the technical capabilities to produce LCDs and to compete worldwide, provided that production investments are made on an appropriate scale for a well-defined technology.

The approach, which is now widely recognised as the most promising, is to deposit a matrix of switching transistors on an inner wall of the LCD (AMLCD). Three of the partners have demonstrated their technical know-how in the field of active matrix panels by the realisation, at the laboratory level, of displays with viewing areas of approximately 10 x 10 cm{2} and resolution up to 256 x 256 pixels (see project 833).

Although applications for such displays are expected in small portable equipment and video projectors, it seems necessary to develop larger (A4) high-resolution panels to meet the key requirements of office terminals. The main goal of the project is therefore to validate technologies for the production of active matrix LCDs up to A4 in size.

There are a number of European companies with the technical capabilities to produce liquid crystal displays (LCD) and to compete worldwide, provided that production investments are made on an appropriate scale for a well defined technology. Such a display, compact and operating at low voltage, must be able to show colour and grey scale with high resolution and should be less bulky than current cathode ray tube (CRT) devices in orderto fulfil office systems requirements in the near future.

The main goal of the project is therefore to validate technologies for the production of active matrix LCD up to A4 in size. The work involves the preparation of direct view flat panel displays using amorphous silicon wilth external integrated circuit (IC) drivers in the short term, or using polycrystalline silicon with integrated drivers as an alternative in the longer term. During the first 3 years of the project the realization of an A4 amorphous silicon matrix will be carried out, and, in parallel, a polycrystalline silicon process with integrated drivers and A4 glass compatibility, including A4 specific equipment, will be developed (6 inch diagonal demonstrator).

A complete new facility dedicated to the realization of 14 inch x 14 inch substrate displays has been built near Grenoble, and is already experiencing problems arising form amorphous silicon display production in a pilot line. A5 8-colour displays have been demonstrated as a first step towards the final goal. The processing of the panels is on course. The consortium recently demonstrated a 2.8 inch diagonal active matrix LCD display with fully integrated polysilicon row and column drivers. The device contains a 200 x 200 pixel array, and can be driven through a 28-pin connector.

The work involved the preparation of direct-view flat-panel displays using amorphous silicon with external IC drivers in the short term, or using polycrystalline silicon with integrated drivers as an alternative in the longer term.

The company’s obsession with the clarity and accuracy of its displays began with the original Macintosh in 1984 and grew as the platform attracted a large audience of visually-oriented professionals from fields such as graphic design, desktop publishing, photo retouching, and film production. Feedback from these pros only strengthened the quality of Apple’s displays over the years.

Apple spent nearly two decades selling some of the world’s sharpest and most color accurate CRT displays (mostly manufactured by Sony), but the company has truly shined in its pursuit of flat-screen technology, racking up a number of industry firsts since the debut of its first LCD for the Apple IIc in 1984.

So to celebrate Apple’s achievements in visual computer displays, let’s take a look at five of the most important displays Apple has ever released. The following units had the most impact and influence on the computer industry, Apple, and even the wider world as a whole.

design was cutting-edge at the time, and Apple cut no corners choosing its display: they integrated the world’s first active-matrix LCD to appear in a production laptop. Its active-matrix design meant that every pixel of its 640 by 400 screen remained vividly

low yields from a complex and difficult manufacturing process. (In fact, Apple repeatedly delayed production of its first portable machine until active-matrix technology was commercially viable.) Apple took a big gamble by including such a pricey component in its first portable machine; its choice of panel alone forced Apple to sell the Portable at prices over $1000 more than its passive-matrix PC competitors.

The gamble didn’t pay off. The active-matrix LCD drove up the price too high and effectively sunk the Mac Portable in the market. Despite that, the Portable’s display remains important because, as Apple’s first laptop LCD, it set a precedent for ultra-high quality that Apple still chases to this day.

parts. Separately, you had a color TFT flat-panel LCD and a fluidly adjustable mechanical arm. But combined, the two components conjured a kind of magic that turned Apple’s first mainstream LCD-bearing desktop machine into a distinctive triumph.

Sure, Apple could have just stuck the flat panel display in a rectangular box (similar to what we see in iMacs today), but instead the firm chose to debut mainstream desktop LCDs with a distinctive flourish that defined the personality of the machine and maintained Apple’s head-and-shoulders design lead above its competition.

The first Apple desktop LCD that really mattered shipped as part of the iMac G4 in early 2002. It proved that LCDs in iMacs worked, and we still see the results in Apple’s products today.

“The Apple Cinema Display is without a doubt the largest, the most advanced and the most beautiful LCD display ever offered,” said Steve Jobs in the August 1999

It was also (as Jobs mentioned) the largest desktop computer LCD in the world at the time of its release. Apple expertly positioned the new monitor to appeal to a new breed of high-end digital video professionals; its “Cinema” name and wide aspect ratio conveyed that Macs were the ideal platform for editing high definition video and Hollywood movies alike.

30-inches. Today, even iMacs ship with their own “Cinema Displays” (not in name, but in spirit) signifying the importance of the 1999 Cinema Display as a first step into a wider world of expansive monitors.

The 9-inch black and white CRT embedded in every Mac set a new standard for high quality personal computer displays with its sharp, flicker-free, almost paper-white display. Apple included it out of necessity, since the Mac needed to accurately render what was then considered a very high resolution bitmapped image.

But critics loved it anyway. At a time when many business-class personal computers shipped with green- or amber-screen monochrome displays, the Mac’s white phosphor CRT lent itself very well to the simulation of paper in desktop publishing software that would become the hallmark of the Macintosh. The display set a high bar for quality that Apple has rarely deviated from over the past 30 years.

Japan Display Inc. (JDI) has announced its development of a new display technology known as a “Full Active” panel. The new design boasts that it can reduce the width of the bottom bezel down to as narrow as the other three sides, potentially reducing the size of smartphones using this display type. To coincide with the announcement, the company also introduced a 5.5-inch 1080p LCD display for smartphones built on this technology.

The “Full Active” name seems to be a bit of misnomer though. The display technology still appears to operate using the traditional LCD active-matrix method of controlling individual pixels using capacitors and transistors.

Instead, JDI says that it has managed to decrease the bezel requirements for its new display by adopting a new high-density wiring layout, along with new processing and module assembly technologies. Essentially, the company has managed to pack extra wiring into the display itself, which reduces the extra space usually required at the bottom of the LCD.

Since the Company’s inception by a team of enterprising academics at the University of Hong Kong in 1978, Varitronix have grown to become one of the leading manufacturers of Liquid Crystal Displays through years of innovation in research, design, production scalability, and technology advancement.

Through the following years of finding local success, Varitronix envisioned a much larger scale operation for the ever-increasing demand for displays. The trajectory plan eventually led the Company to be officially listed on the Hong Kong Stock Exchange in 1991 (HKSE code: 710), continuing its influence and strong presence to serve customers at the local, national, and global levels.

This new range of TFT LCD displays with unique characteristics come with the standard interfaces including MiPi, SPI, RGB, DisplayPort and eDP. However, to aid our customers and increase our flexibility of interfacing we are also offering proprietary interface boards which allow you to simply interface via the HDMI / USBC inputs. If you would like more information on this interface board, then please just contact us.

Another major development, available on most of the new range, is the full active LED dimming backlighting which is a technology improvement on edge lit displays. This new technology allows you to control certain parts of the screen and to optimize colours and shades.

On one side, it pushes the video to the LCD layer but on the other side, it processes the video, decides what the best brightness should be for each and every section of the LCD (divided into zones) based upon the image that is on it. Then it tells each LED what brightness to be for optimisation. The result is that the blacks are darker, the whites are brighter, and everything in between is more in tune with what they should be. And this is happening 60 times per second, wow, what a performance for optimization process!

You can achieve true HDR (High-dynamic-range) and can exceed HDR1000* specs.  The dynamic contrast ratio is virtually unlimited and as you can see can reach 10 Million to one (10M:1) and you can achieve peak brightness that’s daylight readable but have the colour and brightness depth of an OLED display.  We are seeing great interest in these displays in areas such as broadcast, medical and automotive industries as they value the quality of the image and performance that standard TFTs cannot offer.

What is an active-matrix liquid crystal display? Also known as TFT Display, or Thin Film Transistor Display. An active matrix liquid crystal display is the display industry’s term for the type of flat panel display that is currently the overwhelming choice of notebook computer manufacturers, due to light weight, very good image quality, wide color gamut, and response time. With active matrix displays, each pixel is controlled by a switch-device which actively maintains the pixel state while other pixels are being addressed. This generally makes the screens faster, brighter, and more colorful then passive matrix control of each pixel, while preventing crosstalk from inadvertently changing the state of an unaddressed pixel.