mac lcd screen manufacturer

Apple is always looking to diversify its suppliers; this helps to improve existing technologies and make them less expensive. This time, TCL’s subsidiary CSOT wants to enter Apple’s LCD supply chain for upcoming Macs and iPads.

The publication says that CSOT is a “fierce competitor” to BOE in the global LCD market, but the company is ahead of CSOT in LCD panels for notebooks, tablets, and monitors as well as with the OLED technology for smartphones.

BOE, as you probably know, has for years been a third supplier of displays for Apple’s older LCD iPhones, but only started making OLED panels for Apple as of the iPhone 12. It was on track to pick up orders for 30-40M iPhones this year. It will also be responsible for around five million units of iPhone 14 OLED panels.

Not only that, but BOE is also supplying LCD panels to Apple for MacBooks and iPads. Analyst firm Omdia says the Chinese company will be the largest supplier of LCD panels for iPad this year.

CSOT also formed a team during the first half of the year to review building an OLED production line aimed at iPhones. CSOT’s expansion plan will, besides BOE, also threaten South Korean display maker LG Display, which leads the supply of LCD panels to Apple for high-end devices.

LG Display is expected to supply 14.8 million LCD panels to Apple for MacBooks this year, according to Omdia, making its share in this specific supply chain 55%. Having another competitor in the supply chain like CSOT could add pressure on LG Display to cut unit prices.

mac lcd screen manufacturer

Apple"s MacBook and iPad screen vendor is looking to challenge Samsung"s and LG"s OLED stranglehold for the iPhone, giving Apple yet another supplier to leverage in price negotiations.

BOE Technology has supplied displays for Apple since 2015, and is the worlds largest producer of laptop LCD displays. According to sources familiar with the matter, the company seeks a toehold in the OLED supply for the iPhone, Apple Watch, and anything else the company is considering using the technology.

That 70 percent is the low-end of efficiency required to be able to make money on the screen production. However, it is unclear if the company can maintain that if it ramps up to the volumes that Apple would need for the iPhone.

BOE is the only Chinese company that provides screens to Apple. It is also controlled by the Beijing city government, with its largest shareholders state-held companies.

A traditional LCD screen is considered transmissive — individual elements change color, but are at the mercy of assorted backlight technologies for presentation. OLED screens are emissive, meaning that each individual pixel is its own light source with brightness being able to be set per pixel.

As a result, OLED technology also has significant power efficiency improvements over LCD screens. For instance, a black pixel consumes no power— this also opens up other utilizations of an OLED screen, such as only using a small portion of it for a constant time and notification display, with minimal impact to battery life.

Without the need for a backlight, an OLED screen can be thinner than competing technologies, all other factors equal. OLED response times can theoretically reach 0.01 milliseconds, versus 1 millisecond for modern LCD screens.

Production is more complicated than LCD, with even a speck of dust completely ruining a screen during initial fabrication. The cost to construct each screen still exceeds that of an LCD.

Water impingement is a major problem for OLED screens both during production, and in-use. Even a small amount of water contacting the organic substrate of the screen can immediately damage the display, necessitating replacement.

Partly because of these factors, LG has been slow to transition its manufacturing lines over to the new technology. As a result, rumors about LG getting involved in OLED screen production for Apple"s iPhone have taken a long time to develop.

mac lcd screen manufacturer

Retina Display is a brand name used by Apple for its series of IPS LCD and OLED displays that have a higher pixel density than traditional Apple displays.trademark with regard to computers and mobile devices with the United States Patent and Trademark Office and Canadian Intellectual Property Office.

The Retina display debuted in 2010 with the iPhone 4 and the iPod Touch (4th Generation), and later the iPad (3rd generation) where each screen pixel of the iPhone 3GS, iPod touch (3rd generation), iPad 2 was replaced by four smaller pixels, and the user interface scaled up to fill in the extra pixels. Apple calls this mode HiDPI mode. In simpler words, it is one logical pixel = four physical pixels. The scale factor is tripled for devices with even higher pixel densities, such as the iPhone 6 Plus and iPhone X.

The Retina display has since expanded to most Apple product lines, such as Apple Watch, iPhone, iPod Touch, iPad, iPad Mini, iPad Air, iPad Pro, MacBook, MacBook Air, MacBook Pro, iMac, and Pro Display XDR, some of which have never had a comparable non-Retina display.marketing terms to differentiate between its LCD and OLED displays having various resolutions, contrast levels, color reproduction, or refresh rates. It is known as Liquid Retina display for the iPhone XR, iPad Air 4th Generation, iPad Mini 6th Generation, iPad Pro 3rd Generation and later versions,Retina 4.5K display for the iMac.

Apple"s Retina displays are not an absolute standard for display sharpness, but vary depending on the size of the display on the device, and at what distance the user would typically be viewing the screen. Where on smaller devices with smaller displays users would view the screen at a closer distance to their eyes, the displays have more PPI (Pixels Per Inch), while on larger devices with larger displays where the user views the screen further away, the screen uses a lower PPI value. Later device versions have had additional improvements, whether an increase in the screen size (the iPhone 12 Pro Max), contrast ratio (the 12.9” iPad Pro 5th Generation, and iMac with Retina 4.5K display), and/or, more recently, PPI count (OLED iPhones); as a result, Apple uses the names “Retina HD display", "Retina 4K/5K display", “Retina 4.5K display", "Super Retina HD display", “Super Retina XDR display”, and "Liquid Retina display" for each successive version.

When introducing the iPhone 4, Steve Jobs said the number of pixels needed for a Retina display is about 300 PPI for a device held 10 to 12 inches from the eye.skinny triangle with a height equal to the viewing distance and a top angle of one degree will have a base on the device"s screen that covers 57 pixels. Any display"s viewing quality (from phone displays to huge projectors) can be described with this size-independent universal parameter. Note that the PPD parameter is not an intrinsic parameter of the display itself, unlike absolute pixel resolution (e.g. 1920×1080 pixels) or relative pixel density (e.g. 401 PPI), but is dependent on the distance between the display and the eye of the person (or lens of the device) viewing the display; moving the eye closer to the display reduces the PPD, and moving away from it increases the PPD in proportion to the distance.

The displays are manufactured worldwide by different suppliers. Currently, the iPad"s display comes from Samsung,LG DisplayJapan Display Inc.twisted nematic (TN) liquid-crystal displays (LCDs) to in-plane switching (IPS) LCDs starting with the iPhone 4 models in June 2010.

Reviews of Apple devices with Retina displays have generally been positive on technical grounds, with comments describing it as a considerable improvement on earlier screens and praising Apple for driving third-party application support for high-resolution displays more effectively than on Windows.T220 and T221 had been sold in the past, they had seen little take-up due to their cost of around $8400.

"to our eyes, there has never been a more detailed, clear, or viewable screen on any mobile device. Not only are the colors and blacks deep and rich, but you simply cannot see pixels on the screen…webpages that would be line after line of pixelated content when zoomed out on a 3GS are completely readable on the iPhone 4, though the text is beyond microscopic."

The sort of rich, data-dense information design espoused by Edward Tufte can now not only be made on the computer screen but also enjoyed on one. Regarding font choices, you not only need not choose a font optimized for rendering on screen, but should not. Fonts optimized for screen rendering look cheap on the retina MacBook Pro—sometimes downright cheesy—in the same way they do when printed in a glossy magazine.

Apple fan website CultOfMac hosts an article by John Brownlee"Apple"s Retina Displays are only about 33% of the way there."visual acuity in the population saying "most research suggests that normal vision is actually much better than 20/20" when in truth the majority have worse than 20/20 vision,WHO considers average vision as 20/40.presbyopia

The first smartphone following the iPhone 4 to ship with a display of a comparable pixel density was the Nokia E6, running Symbian Anna, with a resolution of 640 × 480 at a screen size of 62.5mm. This was an isolated case for the platform however, as all other Symbian-based devices had larger displays with lower resolutions. Some older Symbian smartphones, including the Nokia N80 and N90, featured a 2.1 inch display at 259 ppi, which was one of the sharpest at the time. The first Android smartphones with the same display - Meizu M9 was launched a few months later in beginning of 2011. In October of the same year Galaxy Nexus was announced, which had a display with a better resolution. By 2013 the 300+ ppimark was found on midrange phones such as the Moto G.Samsung Galaxy S4 and HTC One (M8) had 1080p (FHD) screens around 5-inches for a 400+ PPI which surpassed the Retina density on the iPhone 5. The second major redesign of the iPhone, the iPhone 6, has a 1334 × 750 resolution on a 4.7-inch screen, while rivals such as the Samsung Galaxy S6 have a QHD display of 2560 × 1440 resolution, close to four times the number of pixels found in the iPhone 6, giving the S6 a 577 PPI that is almost twice that of the iPhone 6"s 326 PPI.

The larger iPhone 6 Plus features a "Retina HD display", which is a 5.5-inch 1080p screen with 401 PPI. Aside from resolution, all generations of iPhone Retina displays receive high ratings for other aspects such as brightness and color accuracy, compared to those of contemporary smartphones, while some Android devices such as the LG G3 have sacrificed screen quality and battery life for high resolution. Ars Technica suggested the "superfluousness of so many flagship phone features—the move from 720p to 1080p to 1440p and beyond...things are all nice to have, but you’d be hard-pressed to argue that any of them are essential".

mac lcd screen manufacturer

Apple Inc. sold a variety of LCD and CRT computer displays in the past. Apple paused production of their own standalone displays in 2016 and partnered with LG to design displays for Macs.Pro Display XDR was introduced, however it was expensive and targeted for professionals. Nearly three years later, in March 2022, the Studio Display was launched as a consumer-targeted counterpart to the professional monitor. These two are currently the only Apple-branded displays available.

Apple"s manufacture history of CRT displays began in 1980, starting with the Apple III business computer. It was a 12″ monochrome (green) screen that could display 80×24 text characters and any type of graphics, however it suffered from a very slow phosphor refresh that resulted in a "ghosting" video effect. So it could be shared with Apple II computers, a plastic stand was made available to accommodate the larger footprint of the display.

In 1986 came the introduction of the AppleColor RGB Monitor, a 12″ analog RGB display designed specifically for the Apple IIGS computer. It supported a resolution of 640×400 interlaced (640×200 non-interlaced) and could be used by the Macintosh II, in a limited fashion, with the Apple High Resolution Display Video Card. Also introduced that year was the Apple Monochrome Monitor, which cosmetically was identical to the former model but was a black and white composite display suitable in external appearance for the Apple IIGS, Apple IIc or Apple IIc Plus.

The second generation of displays were built into the Lisa and Macintosh computers. The Macintosh had a 9-inch monochrome display that could display 512×342 pixels which would be used in all monochrome Compact Macintosh computers.

A new external AppleColor High-Resolution RGB Monitor was introduced in 1987 for the Macintosh II. It had a 13″ Trinitron CRT (the first Apple display to use an aperture grille CRT) with a fixed resolution of 640×480 pixels. The Macintosh II was a modular system with no internal display and was able to drive up to six displays simultaneously using multiple graphics cards. The desktop spanned multiple displays, and windows could be moved between displays or straddle them. In 1989, Apple introduced a series of monochrome displays for the Macintosh, the 20″ Macintosh Two Page Monochrome Display which could display two pages side by side, the 15″ Macintosh Portrait Display with a vertical orientation to display one page, and the 12″ High-Resolution Monochrome Monitor. In 1990, two 12″ displays were introduced for the low end, a 640×480 monochrome model and a 512×384 color model (560×384 for compatibility with Apple IIe Card), meant for the Macintosh LC. These were succeeded by the Apple Macintosh 16″ Color Display, and Apple Macintosh 20″ Color Display with resolutions of 640×480, 832×624 and 1152×870, respectively. There were also the Apple Performa Plus Display (a low-end Goldstar-built 14″ display with 640×480 resolution) for the Macintosh Performa series and the Apple Color Plus 14″ Display.

The Macintosh Color Classic introduced a 10″ color Trinitron display to the Classic compact Macintosh, with a slightly enhanced resolution of 512×384 (560×384 to accommodate the Apple IIe Card) like the standalone 12″ color display. Apple continued the all-in-one series with the larger 14″ Macintosh LC 500 series, featuring a 14″, 640×480 Trinitron CRT until the LC 580 in 1995, which heralded the switch to shadow mask CRTs for the remainder of Apple"s all-in-one computers until the switch to LCDs in 2002. The last Macintosh to include an integrated CRT was the eMac, which boosted the display area to 17″ with support up to 1280×960 resolution. It used a 4th generation flat-screen CRT and was discontinued in 2006.

The fourth generation of displays were introduced simultaneously with the Blue & White Power Macintosh G3 in 1999, which included the translucent plastics of the iMac (initially white and blue "blueberry", then white and grey "graphite" upon the introduction of the Power Mac G4). The displays were also designed with same translucent look. The Apple Studio Display series of CRT displays were available in a 17″ Diamondtron and a 21″ Trinitron CRT, both driven by an LG-Manufactured chassis. The 17″ displays were notorious for faulty flybacks and failing in a manner that could destroy the monitor and catch fire. It"s also reported that these monitors can destroy GPU"s, and sometimes the entire computer. The last Apple external CRT display was introduced in 2000 along with the Power Mac G4 Cube. Both it and the new LCD Studio Displays featured clear plastics to match the Cube, and the new Apple Display Connector, which provided power, USB, and video signals to the display through a single cable. It was available only in a 17″ flat screen Diamondtron CRT. It was discontinued the following year.

The history of Apple LCDs started in 1984 when the Apple Flat Panel Display was introduced for the Apple IIc computer, principally to enhance the IIc"s portability (see Apple IIc Portability enhancements). This monochrome display was capable of 80 columns by 24 lines, as well as double hi-res graphics, but had an odd aspect ratio (making images look vertically squished) and required a very strong external light source, such as a desk lamp or direct sunlight to be used. Even then it had a very poor contrast overall and was quite expensive (US$600), contributing to its poor sales and consequently it dropping from the market not long after its introduction. An estimated 10,000 IIc LCD displays were produced.

The next attempt at a flat panel was with the Macintosh Portable. More of a "luggable" than a laptop, it contained a high-resolution, active-matrix, 1-bit black & white, 9.8″ LCD with 640×400 resolution. Like the IIc Flat Panel, it was not backlit and required a bright light source to be used. A second generation model employed a backlit LCD. The PowerBook and MacBook series would continue to use LCD displays, following an industry-wide evolution from black-and-white to grayscale to color and ranging from 9″ to 17″. Two primary technologies were used, active matrix (higher quality and more expensive) and passive matrix displays (lower quality and cheaper). By 1998 all laptops would use active-matrix color LCDs, though the Newton products and eMate portables would continue to use black and white LCDs. Apple"s current MacBook portable displays include LED backlighting and support either 2560×1600 or 2880×1800 pixel resolutions depending on screen size. The iPod series used black-and-white or color LCDs, the iPhone line uses LCD and OLED displays, and the Apple Watch uses OLED.

In 1997, Apple released the Twentieth Anniversary Macintosh (TAM), its first all-in-one desktop with an LCD display. Drawing heavily from PowerBook technology, the TAM featured a 12.1″ active matrix LCD capable of displaying up to 16 bit color at 800×600. While Apple chose to retain traditional and cheaper CRTs for its all-in-one desktop line for the next 4 years, the TAM is undoubtedly the predecessor for the successful LCD-based iMac line of all-in-one desktops starting with the iMac G4 released in 2002. A substantial upgrade over the TAM, it contained a 15″ LCD supporting up to 1024×768 resolution. It was followed by a 17″ and 20″ models boasting resolution of up to 1680 × 1050. In 2005, the iMac G5 dropped the 15″ configuration and in 2007, the new iMac dropped the 17″ and added a 24″ to the line-up, further boosting resolution to 1920 x 1200. In October 2009, new iMac models moved to 16:9 aspect ratio screens at 21.5 and 27 inches.

The first desktop color flat-panel was introduced on March 17, 1998, with the 15″ Apple Studio Display (15-inch flat panel) which had a resolution of 1024×768. After the eMate, it was one of the first Apple products to feature translucent plastics, two months before the unveiling of the iMac. Apple called its dark blue color "azul". It had a DA-15 input as well as S-video, composite video, ADB and audio connectors, though no onboard speakers. In January 1999 the coloring was changed to match the blue and white of the new Power Macintosh G3s, and the connector changed to DE-15 VGA.

The 22″ widescreen Power Mac G4 and in the beginning was sold only as an option to the Power Mac G4, selling for US$3,999. It had a native resolution of 1600×1024 and used a DVI connector. The display had a striped look on the bezel, similar to previous Studio Displays and iMacs. In December, the colors of the 15″ display were changed to "graphite" to match the new Power Mac G4s, and the input was changed from VGA to DVI, the audio and video features dropped, and the ADB functionality replaced by a two-port USB hub.

In 2000 the 22″ Cinema Displays switched to the ADC interface, and the 15″ Studio Display was remodeled to match the Cinema Display"s easel-like form factor and also featured the Apple Display Connector. In 2001 an LCD-based 17″ Studio Display was introduced, with a resolution of 1280×1024. In 2002 Apple introduced the

In 2004 a new line was introduced, utilizing the same 20″ and 23″ panels alongside a new 30″ model, for $3,299. The displays had a sleek aluminum enclosure with a much narrower bezel than their predecessors. The 20″ model featured a 1680×1050 resolution, the 23″ 1920×1200, and the 30″ 2560×1600. The 30″ version requires a dual-link interface, because a single-link DVI connection (the most common type) doesn"t have enough bandwidth to provide a picture to a display of this resolution. Initially, the only graphics cards that could power the new 30″ display were the Nvidia GeForce 6800 DDL series, available in both GT and Ultra forms. The DDL suffix signified the dual-link DVI capability. The less expensive of the two cards retailed for US$499, raising the net cost of owning and using the display to nearly $3,800. Later graphics options included the NVIDIA Quadro FX 4500; the card included two dual-link DVI connectors which allowed a Power Mac G5 to run two 30″ Cinema Displays simultaneously with the total number of pixels working out to 8.2 million.

In 2006 along with the introduction of the Mac Pro, Apple lowered the price of the 30″ Cinema Display to US$1999. The Mac Pro featured an NVIDIA GeForce 7300GT as the graphics card in its base configuration which is capable of running a 30″ Cinema Display and another 23″ display simultaneously. The Mac Pro is also available with both the ATI Radeon X1900XT card and the NVIDIA Quadro FX 4500 as build-to-order options. Each of these cards is capable of driving two 30″ Cinema Displays.

With the introduction of the Unibody MacBook family, Apple introduced the 24-inch LED Cinema Display, its first desktop display to use the new Mini DisplayPort connector, and also the first with an LED-backlit LCD. It had built-in speakers, a powered 3-port USB hub on the rear, an iSight camera and microphone, and a MagSafe power adapter for laptops. It also connected by USB for peripherals. It has a resolution of 1920×1200 and retailed for US$899.00. In 2010 it was replaced with a new 27-inch version with a resolution of 2560×1440.

After Apple discontinued production of standalone displays in 2016, they partnered with LG to design the UltraFine line, with a 21.5-inch 4K display and 27-inch 5K display (27MD5KA-B), released in November 2016 alongside the Thunderbolt 3-enabled MacBook Pro.USB-C connector, with the 27-inch version integrating Thunderbolt 3 connectivity. On the rear of the displays is a three port USB-C hub. The 21.5-inch version provides up to 60W charging power, while the 27-inch provides up to 85W. The 21.5-inch is compatible with all Macs with a USB-C port, while the 27-inch version can only be used natively at full resolution with Macs with Thunderbolt 3, which includes all Macs with USB-C except the Retina MacBook. The 27-inch model is compatible with older Thunderbolt 2-equipped Macs using an adapter, but is limited to displaying their maximum output resolution.

Standard 15-pin high-density DE-15 VGA connector, first included on some Power Macintosh 9600 models and most PowerPC PowerBooks, and available on all current Macintoshes via a short adaptor cable.

The Apple Display Connector (ADC), which carries DVI, VGA, USB and power in one connector, was used on the PowerMac G4 and early models of the PowerMac G5.

A DVI connector was used on the 2001-2002 titanium PowerBook G4; all aluminum PowerBook G4 15” and 17”; all aluminum MacBook Pro 15″ and 17″ models; Mac Mini G4, Power Mac G4, G5; Intel Mac Mini, and Mac Pro 2006–2012. PowerBook G4 12”, iMac G5 and Intel white iMacs mini-DVI ports.

A mini-VGA connector, which can provide VGA via a short adaptor cable. It appears on the white iBook, eMac, iMac G4 and G5, and first generation 12-inch PowerBook G4. Later models also support a composite and S-video adapter attached to this port.

The Retina MacBook introduced USB-C connectivity for displays. The 2016 MacBook Pro uses a combination Thunderbolt 3 USB-C connector. They are backwards compatible with HDMI and DisplayPort.

The Apple Video Adapter was specially designed to allow users to connect to S-video or composite video devices. The video adapter cable plugs into the video output port (Mini-VGA) built into the back of certain Macintosh computers. The video output port supports VGA, S-Video and Composite video out. The Apple Video Adapter is for S-Video or Composite video output only, use a separate Apple VGA Adapter for VGA video output options. With the Apple Video Adapter you can connect to your TV, VCR, or overhead projector via S-Video or Composite cables.

The Apple VGA Display Adapter was specially designed to allow users to connect certain Macintosh computers to an extra VGA display or external projector (equipped with VGA) for 24-bit video-mirroring. The VGA cable from your external display or projector cable plugs into the Mini-VGA video port built into your Macintosh via the Apple VGA Display Adapter.

Compatible with: eMac, iMac G5, iMac G4 flat-panel, 12-inch PowerBook G4, or iBooks having a Mini-VGA port. Most Macintosh computers with the Mini-VGA port can also use the Apple Video Adapter for S-video & Composite output options.

12-inch PowerBook G4 (first generation) models supported video-mirroring and extended video desktop modes through a mini-VGA port. All 15 and 17 inch PowerBook G4 models have a DVI port as well as an S-Video out port. The mini-VGA port on the 12-inch PowerBook was replaced by a mini-DVI port starting with the second revision of the machine.

"Apple"s Online Store Now Offering New 5K 27-Inch LG UltraFine Display". www.macrumors.com. Archived from the original on September 26, 2022. Retrieved April 3, 2020.

mac lcd screen manufacturer

This is the 13.3" LCD TFT Display and backlight for the MacBook 13". This is the LCD only. This does not include hinges, casing, display cables, etc... If you have a cracked LCD or dark black blotches on your display, this is the only part you need. Apple does not manufacture LCD panels. They use several different manufacturers. The panels we sell are the same manufacturer and part number that originally went into the Macbook. It will be the same quality and type currently in your system. These panels are 100% compatible in every type of 13" Macbook with model number A1181. If you have a 13" Macbook (Black or White) this panel is a direct replacement for your machine. One Year Warranty on all parts and labor!

mac lcd screen manufacturer

This is the 13.3" LCD TFT Display and backlight for the MacBook Air 13" A1237 and A1304 models. This is the LCD and backlight only. This does not include hinges, casing, display cables, etc...T If you have a cracked LCD or dark black blotches on your display, this is the only part you need. Apple does not manufacture LCD panels. They use several different manufacturers. The panels we sell are the same manufacturer and part number that originally went into the Macbook. It will be the same quality and type currently in your system. These panels are 100% compatible in every type of pre-2010 13" Macbook Air. One Year Warranty on all parts and labor!

mac lcd screen manufacturer

Every aspect of the light imaging system in Pro Display XDR is crucial to the overall quality of what you see onscreen. Each element builds on top of the last to create a display with unbelievable brightness and contrast.

Typical LCDs are edge-lit by a strip of white LEDs. The 2D backlighting system in Pro Display XDR is unlike any other. It uses a superbright array of 576 blue LEDs that allows for unmatched light control compared with white LEDs. Twelve controllers rapidly modulate each LED so that areas of the screen can be incredibly bright while other areas are incredibly dark. All of this produces an extraordinary contrast that’s the foundation for XDR.

Pro Display XDR extends exceptional image quality to the very edge. To ensure that LEDs along the sides of the display mix well with adjacent ones, a micro-lens array boosts light along the edges. This creates uniform color and brightness across the entire screen.

With a massive amount of processing power, the timing controller (TCON) chip utilizes an algorithm specifically created to analyze and reproduce images. It controls LEDs at over 10 times the refresh rate of the LCD itself, reducing latency and blooming. It’s capable of multiple refresh rates for amazingly smooth playback. Managing both the LED array and LCD pixels, the TCON precisely directs light and color to bring your work to life with stunning accuracy.

mac lcd screen manufacturer

Apple is always looking to diversify its suppliers; this helps to improve existing technologies and make them less expensive. This time, TCL’s subsidiary CSOT wants to enter Apple’s LCD supply chain for upcoming Macs and iPads.

The publication says that CSOT is a “fierce competitor” to BOE in the global LCD market, but the company is ahead of CSOT in LCD panels for notebooks, tablets, and monitors as well as with the OLED technology for smartphones.

BOE, as you probably know, has for years been a third supplier of displays for Apple’s older LCD iPhones, but only started making OLED panels for Apple as of the iPhone 12. It was on track to pick up orders for 30-40M iPhones this year. It will also be responsible for around five million units of iPhone 14 OLED panels.

Not only that, but BOE is also supplying LCD panels to Apple for MacBooks and iPads. Analyst firm Omdia says the Chinese company will be the largest supplier of LCD panels for iPad this year.

CSOT also formed a team during the first half of the year to review building an OLED production line aimed at iPhones. CSOT’s expansion plan will, besides BOE, also threaten South Korean display maker LG Display, which leads the supply of LCD panels to Apple for high-end devices.

LG Display is expected to supply 14.8 million LCD panels to Apple for MacBooks this year, according to Omdia, making its share in this specific supply chain 55%. Having another competitor in the supply chain like CSOT could add pressure on LG Display to cut unit prices.

mac lcd screen manufacturer

Replace a display compatible with a 2016 or 2017 model A1706 or A1708 MacBook Pro 13" Retina laptop. Includes the 2560 x 1600 13.3" Retina LCD Screen, Display Cover, Bezel, FaceTime HD Camera, Clutch Hinges, Display Daughter Board, Cable Spring

Replace a display compatible with a Mid 2018 to Mid 2019 model A1989 or A2159 MacBook Pro 13" with laptop. Includes the 2560 x 1600 13.3" Retina LCD Screen, Display Cover, Bezel, FaceTime HD Camera, and Clutch Hinges.

Replace a display compatible with a model A2338 MacBook Pro 13" laptop. Includes the 2560 x 1600 pixel IPS panel with True Tone, Display Cover, Bezel, FaceTime HD Camera, Clutch Hinges, Display Daughter Board, Cable Spring Mechanism.

Replace a display compatible with the model A1502 Early 2015 13" MacBook Pro laptop. Includes the 2560 x 1600 13.3" Retina LCD screen, display cover, bezel, FaceTime HD Camera, clutch hinges, Wi-Fi antenna, camera, and display data cables. Part #661

Replace a display compatible with a 2020 model A2289 MacBook Pro 13" Two Thuderbolt Port laptop. Includes the 2560 x 1600 13.3" Retina LCD Screen, Display Cover, Bezel, FaceTime HD Camera, and Clutch Hinges.

Replace a glossy or anti-glare display panel compatible with the A1278 Late 2008, A1342 Late 2009 to Mid 2010 MacBook 13" Unibody models and A1278 MacBook Pro 13" Unibody model laptop. 1280 x 800 pixel Resolution. 13.3".

Replace a display compatible with the model A1398 Late 2013 to Mid 2014 MacBook Pro 15" Retina laptop. Includes the 2880 x 1800 pixel 15.4" Retina LCD screen, display cover, bezel, FaceTime HD camera, clutch hinges, Wi-Fi antenna, camera, and

Replace a display compatible with the model A1707 late 2016 to 2017 Retina 15" MacBook Pro laptop. Includes the 2880 x 1800 15.4" Retina LCD Screen, Display Cover, Bezel, Camera.

Replace a display compatible with the late 2011 model A1278 13” Unibody MacBook Pro. Includes the front glass, LCD screen, iSight Camera, all antenna cables, all LCD cables, hinges, and clutch cover.

Replace a display compatible with the mid 2012 model A1286 15" Unibody MacBook Pro laptop. Includes the LCD screen, display cover, bezel, FaceTime HD Camera, clutch hinges, LED assembly, Wi-Fi antenna, and display data cables.

Replace a display compatible with a model A2141 2019 16" MacBook Pro laptop. Includes the 3072 x 1920 LCD screen, display cover, bezel, FaceTime HD Camera, and clutch hinges.

Replace a display compatible with a model A2442 2021 14" MacBook Pro laptop. Includes the 3024 x 1964 LCD screen, display cover, camera, and clutch hinges.

Replace a display compatible with a model A2485 2021 16" MacBook Pro laptop. Includes the 3456 x 2234 Liquid Retina XDR mini-LED screen, display cover, camera, and clutch hinges.

Replace an Antenna Cover compatible with the A1212 model 17" MacBook Pro laptop. This part houses the AirPort antenna cable assembly within the clutch cover.

mac lcd screen manufacturer

While Samsung will continue to supply approximately 80 per cent of iPhone displays, rumours claim that a little-known company called BOE looks set to become Apple’s second-largest OLED supplier. Not only is this a sign that Apple’s lowest-cost iPhone 12 model will likely make the leap from LCD to OLED this year, but it’s also a sign that Apple is looking to diversify which manufacturers it uses, and potentially looking to ready itself for a move into the display market itself.

You, like many of us when we first read the rumours, are probably wondering who the hell BOE is, and how it managed to score such a big deal despite its relatively unknown status. However, BOE is, in fact, the largest display manufacturer in China, supplying screens for smartphones, TVs and other electronic devices and home appliances.

The company, which was founded in Bejing in 1993 and acquired SK Hynix"s STN-LCD and OLED businesses back in 2001, is ranked second in the world when it comes to flexible OLED shipments, holding a market share of 11 per cent during the first quarter of this year. It, naturally, is still a long way behind market leader Samsung, which owned 81 per cent market share of the OLED market in the same quarter. Still, with a sizable chunk of the OLED market already under its belt, it perhaps won’t come as too much of a surprise – now, at least – that the firm already has some big-name allies.

BOE’s display technology is currently being utilised in Huawei"s most popular smartphone models, including the high-end P and Mate series, and it reportedly will manufacturer the palm-stretching screen set to appear on this year’s Huawei Mate 40.

BOE even provided the flexible OLED used in the foldable Huawei Mate X, which has proven way more reliable than Samsung’s flexible OLED efforts. Perhaps, then, it’s somewhat unsurprising that Samsung is reportedly considering using BOE screens for its future devices, likely at the expense of its own industry-dominating Samsung Display unit.

BOE’s surprising alliance with Apple isn’t the only time the two companies have worked together, either; the Chinese manufacturer already makes LCD screens for Apple"s older iPhones, and its tiny OLED panels are currently used in some Apple Watch models. It’s unclear how much BOE and Apple’s latest deal is worth, but it’s likely in the billions. According to online reports, Samsung’s deal with the iPhone maker is thought to be worth around $20 billion annually, so if BOE manages to secure 20 per cent of Apple’s display orders going forward, such a deal could be worth as much as $4bn.

Although BOE has managed to muscle its way into Apple’s exclusive list of OLED suppliers, and has invested heavily in facilities and equipment in order to meet the firm’s demands, the new partnership hasn’t got off to a flying start. According to reports, the company’s flexible OLED panels have not yet passed Apple’s final validation. This means, according to rumours, that BOE’s screens might not show up in the first batch of iPhone 12 models, and will instead start shipping on handsets at the beginning of 2021, with Apple instead set to re-increase its reliance on LG in the short term.

The display market could be Apple’s next target. Not only does the company already manufacturer screen technology in the form of its Pro Display XDR, but a recent Bloomberg report claims that Apple is “designing and producing its own device displays” and is making a “significant investment” in MicroLED panels. This technology utilises newer light-emitting compounds that make them brighter, thinner and less power-intense than the current OLED displays.

mac lcd screen manufacturer

You can find out what the manufacturer, model number, and type of LCD panel you have in any of your Macs, including the iMac, MacBook Air, MacBook, or any model MacBook Pro by using a fairly complex looking terminal command.

With the first line being the LCD panel model and the second line being the color profile you are using (same as set in your Display preferences). You can then find out what the manufacturer and specs of the display are by googling for the model number, for instance LTN154BT turns up this page indicating it is a Samsung 15″ display running at 1440×900 and capable of displaying a maximum of 262,000 colors.

This is particularly helpful information to know if your MacBook screen has been cracked and you want to do the installation yourself. Official repairs are often very expensive, but with a little patience and the right tools it can be done by anyone. You can typically pick up an LCD panel through Amazon or eBay for rather cheap and the installation takes about 30 minutes if you follow a guide.

It can also be handy to know if you’re just curious which particular panel or screen type is used in your Mac, since Apple often sources different panels from different manufacturers, but otherwise using them in the same Mac models.

mac lcd screen manufacturer

Nowadays, LCD panels for smartphone displays are taking the back seat while tech companies move towards OLED screens, including Apple. Samsung Display, one of Apple’s suppliers for iPhone, iPad and Apple Watch displays, announced today that it is going to end LCD production in its China-based and South Korean factories by the end of 2020.

Reuters now reports that Samsung is moving on with its factories, but will still supply LCD display orders until the end of the year. The company has two LCD production lines in South Korea and two LCD-dedicated factories in China.

Additionally, Samsung’s spokesperson said that the company has not decided upon a specific plan for the China-based factories yet, but the ones in South Korea are to focus on “quantum dot” screens, which is an advanced technology producing pure monochromatic red, blue and green light, and therefore offering enhanced color schemes and brightness.

The production of LCD displays by Samsung has already been in decline since last year, as demand for LCD screens is continuously decreasing. In October, Samsung closed one of its LCD production lines in South Korea. Additionally, the company stated that it will invest around $10.72 billion in research and improvements for their production lines of quantum dot screens.

mac lcd screen manufacturer

Chen Jun, chief analyst of Qunzhi Consulting, said today that Sharp will become the largest supplier of LCD (liquid crystal) screens for iPhones in the future and continue to increase its B2B business.

Apple’s latest iPhone 11 series currently uses LCD and OLED screens. The 5.8-inch iPhone 11 Pro and the 6.5-inch iPhone 11 Pro Max use OLED screens, while the 6.1-inch iPhone 11 use LCD panels.

As we have reported for many times, Apple’s next-generation iPhone 12 series will include four models. According to the current news, all four models in the series will use OLED screens.

Currently LGD, JDI and Sharp are the main LCD screen suppliers for Apple iPhones. However, LGD will supply OLED screens to Apple next year, thus exiting the list of LCD screen suppliers.

Prior to this, we also reported that the LCD screen required by Apple’s new SE series iPhone is currently exclusively supplied by its previous major LCD screen supplier, Japan Display Company (JDI). However, Sharp, which was acquired by Hon Hai Precision in 2016, subsequently also will supply LCD screens to Apple’s new iPhone SE.

Before the iPhone adopted the OLED screen, JDI was a major supplier of LCD panels for Apple smartphones. And Apple was also the main source of income for JDI. However, after Apple turned to OLED screens, JDI, which was not in time for transition, also fell into trouble. Apple has also rescued from multiple levels. In 2019, JDI still has 61% of revenue from Apple.