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Our new line of 10.1” TFT displays with IPS technology are now available! These 10.1” IPS displays offer three interface options to choose from including RGB, LVDS, and HDMI interface, each with two touchscreen options as capacitive or without a touchscreen.

The new line of 3.5” TFT displays with IPS technology is now available! Three touchscreen options are available: capacitive, resistive, or without a touchscreen.

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Parking rearview priority: the monitor will start up automatically and synchronously display the video from rearview camera when you"re backing your car.

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.

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ASUS Eye Care Monitors Receive Most Number of TÜV Rheinland Low Blue-Light Emissions and Flicker-Free Certifications. ASUS Low Blue Light Monitors feature a OSD menu that allows you to access four different Blue Light Filter settings onscreen. ASUS Flicker-Free technology uses Smart Dynamic Backlight Adjustment to reduce flicker, this protects you from eye fatigue, irritation and strains.

Maradu, Kochi, Dist. Ernakulam 3/355, Planet Tower, Near Thomaspuram Church Kannadikkad-Chambakara Road, Maradu, Kochi - 682304, Dist. Ernakulam, Kerala

We are best name in the market offering best quality array of Car LCD Screen. These offered screens are created assistance of best tools these offered LCD are designed for watching the rear side of the car whole reversing. They are stylish to look at and easy to install. They are light weighted and offer best picture clarityread more...

We offer our client wide range of 9 inch TFT LCD monitor supplier in Chennai which is basically installed in cars. It is widely preferred by our clients because of its superior features as well as performances.

The illustrated vehicles may vary in selected details from the production models and some illustrations feature optional equipment available at additional cost. All information concerning the scope of supply, appearance, services, dimensions and weights is non-binding and specified with the proviso that errors, for instance in printing, setting and/or typing, may occur; such information is subject to change without notice. Please note that model specifications may vary from country to country. In the case of coated surfaces, there may be color differences due to the usual process fluctuations. The consumption values stated refer to the roadworthy series condition of the vehicles at the time of factory delivery.

Manufacturer Suggested Retail Price (MSRP) does not include Pre-delivery Inspection (PDI), titles, licensing, insurance, registration fees, destination charges, environmental charges, added accessories and installation thereof, and dealer added options or any additional dealer charges.

Brand new: Lowest priceThe lowest-priced brand-new, unused, unopened, undamaged item in its original packaging (where packaging is applicable).Packaging should be the same as what is found in a retail store, unless the item is handmade or was packaged by the manufacturer in non-retail packaging, such as an unprinted box or plastic bag.See details for additional description.

Esky Foldable 4.3 inch TFT-LCD Monitor For Car Backup Camera 181-96300-16. Personal item, have one of these installed in one of my cars, had bought another for second car, didn’t set it up. New in box, never used. Backup camera is NOT a part of this kit. This is only the monitor that can be installed using the included 3M tape on the dash. Manual and instructions included. Ships through USPS.

The history of laptops describes the efforts, begun in the 1970s,personal computers that combine the components, inputs, outputs and capabilities of a desktop computer in a small chassis.

The portable micro computer the "Portal" of the French company R2E Micral CCMC officially appeared in September 1980 at the Sicob show in Paris. The Portal was a portable microcomputer designed and marketed by the studies and developments department of the French firm R2E Micral in 1980 at the request of the company CCMC specializing in payroll and accounting. It was based on an Intel 8085 processor, 8-bit, clocked at 2 MHz. It was equipped with a central 64K byte RAM, a keyboard with 58 alphanumeric keys and 11 numeric keys (in separate blocks), a 32-character screen, a floppy disk (capacity - 140,000 characters), a thermal printer (speed - 28 characters/second), an asynchronous channel, a synchronous channel, and a 220-volt power supply. Designed for an operating temperature of 15–35 °C, it weighed 12 kg (26 lb) and its dimensions were 45 × 45 × 15 cm. It ran the Prologue operating system

The Osborne 1 is considered the first true mobile computer by most historians. Adam Osborne founded Osborne Computer and produced the Osborne 1 in 1981. The Osborne 1 had a five-inch screen, incorporating a modem port, two 5+1⁄4-inch floppy drives, and a large collection of bundled software applications. An aftermarket battery pack was available. The computer company was a failure and did not last for very long. Although it was large and heavy compared to today"s laptops, with a tiny 5" CRT monitor, it had a near-revolutionary impact on business, as professionals were able to take their computer and data with them for the first time. This and other "luggables" were inspired by what was probably the first portable computer, the Xerox NoteTaker. The Osborne was about the size of a portable sewing machine, and could be carried on commercial aircraft. The Osborne 1 weighs close to 11 kg (24 lb) and was priced at US$1,795 (equivalent to $5,350 in 2021).

The Compaq Portable was the first PC-compatible portable computer created in 1982. The first shipment was in March 1983 and was priced at US$2,995 (equivalent to $8,410 in 2021). The Compaq Portable folded up into a luggable case the size of a portable sewing machine, similar in size to the Osborne 1. The third model of this development, Compaq Portable II, featured high resolution graphics on its tube display. It was the first portable computer ready to be used on the shop floor, and for CAD and diagram display. It established Compaq as a major brand on the market.

The first significant development towards laptop computing was announced in 1981 and sold from July 1982, the 8/16-bit Epson HX-20.nickel-cadmium batteries, a small (120×32-pixel) dot-matrix LCD with 4 lines of text, 20 characters per line text mode, a 24 column dot matrix printer, a Microsoft BASIC interpreter, and 16 KB of RAM (expandable to 32 KB). The HX-20"s very limited screen and tiny internal memory, made serious word-processing and spreadsheet applications impractical and the device was described as "primitive" by some.

The first clamshell laptop, the Grid Compass, was made in 1982. Enclosed in a magnesium case, it introduced the now familiar design in which the flat display folded shut against the keyboard. The computer was equipped with a 320×200-pixel electroluminescent display and 384 kilobyte bubble memory. It was not IBM-compatible, and its high price (US$8,000–10,000, equivalent to $22,000-28,000 in 2021) limited it to specialized applications. However, it was used heavily by the U.S. military, and by NASA on the Space Shuttle during the 1980s. The GRiD"s manufacturer subsequently earned significant returns on its patent rights as its innovations became commonplace. GRiD Systems Corp. was later bought by the Tandy (now RadioShack) Corporation. The Grid"s portability was restricted as it had no internal battery pack and relied on mains power.

The first contender for true laptop computing was the 16-bit Dulmont Magnum, designed by David Irwin and John Blair of Dulmison, Australia, in 1982 and released in Australia in September 1983 by Dulmont. This battery-powered device included an 80 character × 8 line display in a lid that closed against the keyboard. The Dulmont was thus the first computer that could be taken anywhere and offered significant computing potential on the user"s laptop (though weighing in at 4.8 kg (11 lb)). It was based on the MS-DOS operating system and applications stored in ROM(A:) and also supported removable modules in expansion slots (B: and C:) that could be custom programmed EPROM or standard word processing and spreadsheet applications. The Magnum could suspend and retain memory in battery-backed CMOS RAM, including a RAM Disk (D:). A separate expansion box provided dual 5.25-inch floppy or 10 MB hard disk storage. The product was marketed internationally from 1984 to 1986.Time Office Computers, who relabeled the brand "Kookaburra" and marketed 16- and 25-line LCD display versions.

Two other noteworthy early laptops were the Sharp PC-5000 (similar in many respects to the Dulmont Magnum) and the Gavilan SC, announced in 1983 but first sold in 1984, Gavilan filing bankruptcy the same year. Both ran the 8/16-bit Intel 8088 CPU. The Gavilan was notably the first computer to be marketed as a "laptop". It was equipped with an internal floppy disk drive and a pioneering touchpad-like pointing device, installed on a panel above the keyboard. Like the GRiD Compass, the Gavilan and the Sharp were housed in clamshell cases, but they were partly IBM-compatible, although primarily running their own system software. Both had LCDs, and could connect to optional external printers.

The year 1983 also saw the launch of what was probably the biggest-selling early laptop, the 8-bit Kyocera Kyotronic 85. Owing much to the design of the previous Epson HX-20, and although at first a slow seller in Japan, it was quickly licensed by Tandy Corporation, Olivetti, and NEC, who recognised its potential and marketed it respectively as the TRS-80 Model 100 line (or Tandy 100), Olivetti M-10, and NEC PC-8201.AA batteries. The Tandy"s built-in programs, including a BASIC interpreter, a text editor, and a terminal program, were supplied by Microsoft, and were written in part by Bill Gates himself. The computer was not a clamshell, but provided a tiltable 8 line × 40-character LCD screen above a full-travel keyboard. With its internal modem, it was a highly portable communications terminal. Due to its portability, good battery life (and ease of replacement), reliability (it had no moving parts), and low price (as little as US$300), the model was highly regarded, becoming a favorite among journalists. It weighed less than 2 kg (4.4 lb) with dimensions of 30×21.5×4.5 centimeters (12×8½×1¾ in). Initial specifications included 8 kilobytes of RAM (expandable to 24 KB) and a 3 MHz processor. The machine was in fact about the size of a paper notebook, but the term had yet to come into use and it was generally described as a "portable" computer.

Data General"s introduction of the Data General/One (DG-1) in 1984 is one of the few cases of a minicomputer company introducing a breakthrough PC product. Considered genuinely portable, rather than "luggable", it was a nine-pound battery-powered MS-DOS machine equipped with dual 31⁄2-inch diskettes, a 79-key full-stroke keyboard, 128 KB to 512 KB of RAM, and a monochrome LCD screen capable of either the full-sized standard 80×25 characters or full CGA graphics (640×200).

Although it was not released until 1985, well after the decline of CP/M as a major operating system, the Bondwell 2 is one of only a handful of CP/M laptops. It used an 8-bit Z-80 CPU running at 4 MHz, had 64 KBs of RAM, and a 3.5" floppy disk drive built in, which was unusual for CP/M laptops. The flip-up LCD display"s resolution was 640x200 pixels. Bondwell 2 also included MicroPro"s complete line of CP/M software, including WordStar. The Bondwell 2 was capable of displaying bitmapped graphics. The price of the Bondwell 2 was listed at $995.

Possibly the first commercial IBM-compatible laptop was the 8/16-bit Kaypro 2000, introduced in 1985. With its brushed aluminum clamshell case, it was remarkably similar in design to modern laptops. It featured a 25 line by 80 character LCD, a detachable keyboard, and a pop-up 90 mm (3.5-inch) floppy drive.

Toshiba launched the 8/16-bit Toshiba T1100 in 1985, and has subsequently described it as "the world"s first mass-market laptop computer".Intel 8088, and the display was a monochrome, 640x200 LCD. It was followed in 1987 by the T1000 and T1200. Although limited floppy-based DOS machines, with the operating system stored in ROM on the T1000, the Toshiba models were small and light enough to be carried in a backpack, and could be run from Ni-Cd batteries. They also introduced the now-standard "resume" feature to DOS-based machines: the computer could be paused between sessions without having to be restarted each time.

Also among the first commercial IBM-compatible laptops was the 8/16-bit IBM PC Convertible, introduced in 1986. It had a CGA-compatible LCD and two 720 KB 3.5-inch floppy drives. It weighed 13 pounds (5.9 kg).

The first laptops successful on a large scale came in large part due to a RFP by the U.S. Air Force in 1987. This contract would eventually lead to the purchase of over 200,000 laptops. Competition to supply this contract was fierce and the major PC companies of the time; IBM, Toshiba, Compaq, NEC, and Zenith Data Systems (ZDS), rushed to develop laptops in an attempt to win this deal. ZDS, which had earlier won a landmark deal with the IRS for its Z-171, was awarded this contract for its SupersPort series. The SupersPort series was originally launched with an Intel 8086 processor, dual floppy disk drives, a backlit, blue-and-white STN LCD screen, and a NiCd battery pack. Later models featured a 16-bit Intel 80286 processor and a 20 MB hard disk drive. On the strength of this deal, ZDS became the world"s largest laptop supplier in 1987 and 1988. ZDS partnered with Tottori Sanyo in the design and manufacturing of these laptops. This relationship is notable because it was the first deal between a major brand and an Asian original equipment manufacturer.

Another notable computer was the 8-bit Cambridge Z88, designed by Clive Sinclair, introduced in 1988. About the size of an A4 sheet of paper as well, it ran on standard batteries, and contained basic spreadsheet, word processing, and communications programs. It anticipated the future miniaturization of the portable computer, and as a ROM-based machine with a small display, can – like the TRS-80 Model 100 – also be seen as a forerunner of the personal digital assistant.

By the end of the 1980s, laptop computers were becoming popular among business people. The 16-bit COMPAQ SLT/286 debuted in October 1988, being the first battery-powered laptop to support an internal hard disk drive and a VGA compatible LCD screen. It weighed 14 lb (6.4 kg).

The NEC UltraLite, released in October 1988, was perhaps the first "notebook" computer, weighing just 2 kg (4.4 lb), which was achieved by obviating floppy or hard drive, it was powered by the NEC V30 16-bit CPU. The very restrictive 2 megabyte RAM drive cramped the product"s utility. Although portable computers with clamshell LCD screens already existed at the time of its release, the Ultralite was the first computer in a notebook form-factor. It was significantly smaller than all earlier portable computers and could be carried like a notebook and its clamshell LCD folded over the body like a book cover.

The IBM PS/2 note was a first IBM laptop with clamshell design, and the 1992"s CL57sx model was IBM"s first commercial laptop with color screen;PS/2 port as mobile device option, introduced the laptop BIOSdocking station (IBM Communications Cartridge).

Later PowerBooks featured optional color displays (PowerBook 165c, 1993), and first true touchpad (PowerBook 500 series, 1994), first 16-bit stereo audio, and first built-in Ethernet network adapter (PowerBook 500, 1994).

In 1992, IBM released its ThinkPad 300, 700 and 700C, featuring a clamshell design similar to the PS/2 line. The 700 and 700C (the "C" version came with a color display) came with the distinctive red TrackPoint pointing device that is still used to this day.

Windows 3.1 was the first version of Windows to support APM, which was usually implemented with SMI in the BIOS (introduced with the Intel 80386SL). Windows 95 introduced standardized support for docking via the PnP BIOS (among other things). Prior to this point each brand used custom BIOS, drivers and in some cases, ASICs, to optimize the battery life of its machines. This move by Microsoft was controversial in the eyes of notebook designers because it greatly reduced their ability to innovate; however, it did serve its role in simplifying and stabilizing certain aspects of notebook design.

Windows 95 ushered in the importance of the CD-ROM drive in mobile computing, and helped the shift to the Intel Pentium processor as the base platform for notebooks. The Gateway Solo was the first notebook introduced with a Pentium processor and a CD-ROM. Also featuring a removable hard disk drive and floppy drive, the Solo was the first three-spindle (optical, floppy, and hard disk drive) notebook computer, and was extremely successful within the consumer segment of the market. In roughly the same time period the Dell Latitude, Toshiba Satellite, and IBM ThinkPad were reaching great success with Pentium-based two-spindle (hard disk and floppy disk drive) systems directed toward the corporate market.

Improved battery technology. The heavy lead-acid batteries were replaced with lighter and more efficient technologies, first nickel cadmium or NiCd, then nickel metal hydride (NiMH) and then Lithium-ion battery and lithium polymer.

Power-saving processors. While laptops in 1989 were limited to the 80286 processor (often Harris CMOS) because of the energy demands of the more powerful 80386 on the original CHMOS III process, the introduction of the Intel 386SL processor, designed for the specific power needs of laptops, marked the point at which laptop needs were included in CPU design. The 386SL integrated a 386SX core with a memory controller and this was paired with an I/O chip to create the SL chipset. It was more integrated than any previous solution although its cost was higher. It was heavily adopted by the major notebook brands of the time. Intel followed this with the 486SL chipset which used the same architecture. However, Intel had to abandon this design approach as it introduced its Pentium series. Early versions of the mobile Pentium required TAB mounting (also used in LCD manufacturing) and this initially limited the number of companies capable of supplying notebooks. However, Intel did eventually migrate to more standard chip packaging. One limitation of notebooks has always been the difficulty in upgrading the processor which is a common attribute of desktops. Intel did try to solve this problem with the introduction of the MMC for mobile computing. The MMC was a standard module upon which the CPU and external cache memory could sit. It gave the notebook buyer the potential to upgrade their CPU at a later date, eased the manufacturing process somewhat, and was also used in some cases to skirt U.S. import duties as the CPU could be added to the chassis after it arrived in the U.S. Intel stuck with MMC for a few generations but ultimately could not maintain the appropriate speed and data integrity to the memory subsystem through the MMC connector. A more specialized power saving CPU variant for laptops is the PowerPC 603 family.5300, 2400, 500 upgrades. What started out as a laptop processor was eventually used across all platforms in its follow up, the PowerPC 750 AKA G3.

Improved Liquid-crystal displays, in particular active-matrix TFT (Thin-film transistor) LCD technology. Early laptop screens were black and white, blue and white, or grayscale, STN (Super Twist Nematic) passive-matrix LCDs prone to heavy shadows, ghosting and blurry movement (some portable computer screens were sharper monochrome plasma displays, but these drew too much current to be powered by batteries). Color STN screens were used for some time although their viewing quality was poor. By about 1991, two new color LCD technologies hit the mainstream market in a big way; Dual STN and TFT. The Dual STN screens solved many of the viewing problems of STN at a very affordable price and the TFT screens offered excellent viewing quality although initially at a steep price. DSTN continued to offer a significant cost advantage over TFT until the mid-90s before the cost delta dropped to the point that DSTN was no longer used in notebooks. Improvements in production technology meant displays became larger, sharper, had higher native resolutions, faster response time and could display color with great accuracy, making them an acceptable substitute for a traditional CRT monitor.

Improved storage technology. Early laptops and portables had only floppy disk drives. As thin, high-capacity hard disk drives with higher reliability and shock resistance and lower power consumption became available, users could store their work on laptop computers and take it with them. The 3.5" HDD was created initially as a response to the needs of notebook designers that needed smaller, lower power consumption products. With continuing pressure to shrink the notebook size even further, the 2.5" HDD was introduced. One Laptop Per Child (OLPC) and other new laptops use Flash RAM (non volatile, non mechanical memory device) instead of the mechanical hard disk.

Improved connectivity. Internal modems and standard serial, parallel, and PS/2 ports on IBM PC-compatible laptops made it easier to work away from home; the addition of network adapters and, from 1997, USB, as well as, from 1999, Wi-Fi, made laptops as easy to use with peripherals as a desktop computer. Many newer laptops are also available with built-in 3G Broadband wireless modems.

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

Interior Trim -inc: Simulated Wood/Metal-Look Instrument Panel Insert, Metal-Look Door Panel Insert, Metal-Look Console Insert and Chrome/Metal-Look Interior Accents

Radio: AM/FM Audio System -inc: 6 speakers, 7" touch-screen, Android Auto and Apple CarPlay and Amazon Alexa compatible, USB media port, 2 USB charge ports, hands-free phone capability, advanced voice recognition and music streaming via Bluetooth wireless technology, SiriusXM w/3-month All Access trial and Connected Services including Safety Connect w/1-year trial, Wi-Fi Connect w/up to 2 GB within 3-month trial,