lcd display resolution in stock

Finding the best monitor for you can be a struggle, especially when you’re new to the technical specs. For example, what is monitor resolution? The answer is surprisingly simple once you look at it. At its most basic, monitor resolution is how clearly a monitor can display visual content. The higher the resolution, the clearer the display.

If you’ve ever been shopping for a computer screen or TV you’ve undoubtedly come across one or both of these terms. Today we’ll be diving right in to give you all the info you need to know about monitor resolutions and aspect ratios so you can make the best decision when selecting the right monitor for you.

In addition to a monitor’s panel type, screen size, refresh rate, etc., monitor resolution is usually one of the first specifications considered when shopping for a new monitor. Monitor resolution describes the visual dimensions of any given display. Expressed in terms of width and height, monitor resolution is comprised of a specific number of pixels.

In the case of a monitor with an industry-standard Full HD 1080p resolution, this display has a resolution of 1920 x 1080. This means that the screen will have a width of 1,920 pixels while the height of the screen will be 1,080 pixels. This results in a grand total of 2,073,600 pixels on-screen.

The higher a monitor’s resolution is, the more detailed an image can be because a higher resolution monitor will be made up of more pixels than a lower resolution monitor. This will, of course, depend on the resolution of the content you are viewing. Additionally, more viewable content can fit onto a higher resolution computer screen than on a lower resolution screen.

Pixels, or picture elements, are the smallest physical points on a display, as well as the base components. Pixels are therefore the building blocks of any image you see on your screen. Pixels and resolution are directly correlated and a higher resolution equals a higher number of pixels on a monitor screen.

DPI (dots per inch) indicates the number of dots found within a one-inch line of a scan or print. For monitors and displays, DPI is scrapped in favor of PPI (pixels per inch). While PPI is the correct term when referencing monitors and other displays, both terms are often used interchangeably.

Picture this – you have two monitors side by side, both with a Full HD 1080p Full HD resolution. This means that both have 1,920 horizontal pixels and 1,080 vertical pixels. Now imagine that one screen is a 32-inch screen, while the other is a 25-inch screen. Now you can see how pixel density comes into play because you will have the same number of pixels spread across a larger screen with the 32-inch monitor. Thus, the smaller monitor will have a more densely packed pixel density, resulting in smoother lines and sharper images.

In the example above, the 25-inch monitor would have a pixel density of about 88 ppi, while the 32-inch monitor would have a pixel density of about 69 ppi. In this situation, it’s safe to say that there would be some noticeable differences in image quality between the two, with the 25-inch display providing better-looking images. To take things even further, it is common for smartphones nowadays to have pixel densities ranging from 300 ppi all the way up to over 500 ppi.

The problem here is that the exact point where a higher PPI becomes undetectable is a matter of debate. Some say that the optimal pixel density is somewhere are around 400 ppi, while others say that the pixel density detectable by the eye is closer to 1000 ppi. Since this is a matter of personal preference, it’s always better to test a monitor out for yourself before deciding on which display to buy.

About 720p Resolution: 720p resolution, or 1280 x 720, is a progressive-style monitor resolution. Is it the lowest of the HD-capable resolutions, and is utilized by all widespread HDTV broadcasters.

About 1080p Resolution: 1080p, or 1920 x 1080, is a non-interlaced monitor resolution that is marketed as the first resolution to take full advantage of HD’s complete range of capabilities. 1080p is currently the standard resolution for television, internet streaming services, video games, and smartphones, to name a few.

About 1440p Resolution: 1440p is a progressive resolution containing 2560 x 1440 pixels. Known as ‘Quad HD’, 1440p is 4 times stronger than the base HD variant. 1440p is not fully widespread, but can be found largely within the realm of computing and smartphones, including from well-known companies such as HTC, Samsung, ViewSonic, and Apple.

About 4K Resolution: 4K resolution is so-named due to its horizontal pixel count, although for monitors, 4K resolution is equal to a pixel count of 3840 x 2160. 4K resolution also has 4 times more pixels than 1080p. Although the market share for 4K resolution has increased year-over-year since 2014, its adoption has thus far been limited to internet video streaming, video projection, and commercial televisions.

About 8K Resolution: 8K resolution measures at 7680 x 4320 pixels and is currently the highest monitor resolution currently available. The technology is so new that commercially available 8K UHD televisions and broadcasts are just now becoming available. On the market, 8K is currently being integrated into TVs, computer monitors, and broadcast cameras.

In total pixels, 1080p offers over twice that of 720p, therefore 1080p is sharper and clearer. Other factors aside, although both are considered to be a part of the HD standard, 1080p has been considered the industry standard for monitors for a while now. 720p resolution has already reached peak adoption and is declining in popularity.

With just over 3.6 million pixels, 1440p is just about 1.77 times smoother than 1080p. However, 1080p is the most popular monitor resolution currently on the market, while 1440p is just beginning to gain a foothold.

The aspect ratio of a monitor, like any ratio, is a proportional representation expressed as two distinct numbers separated by a colon. In the case of monitors and displays, the aspect ratio describes the correlation between width and height. Frequently encountered monitor aspect ratios include 4:3, 16:9, and 21:9.

Otherwise known as ‘fullscreen’, the four-by-three aspect ratio was once the standard for films, broadcasts, and computer monitors in the 20th century. With the advent of HD resolutions, 4:3 is no longer quite as common.

When viewing content, 4:3’s fullscreen experience yields a more ‘box-like’ display, while 16:9’s widescreen results in a letter-shaped appearance. In total, 4:3 gives newer media a feeling of being cropped, while 16:9 results in black bars manifesting on the top and bottom of the screen.

While having a monitor with a high resolution is a good start, it doesn’t mean that you can start enjoying all of your content in that resolution. This is because the resolution of an image you see on your screen also depends on the resolution the content you are viewing was recorded in.

Therefore, if a video was recorded in 1080p but you have a 4K monitor, the highest resolution you could watch that video in would be 1080p. Conversely, if you had a 1080p monitor and your video content was shot in 4K, you would still be able to watch the video but the resolution of the video would be limited to 1080p.

Luckily though, more and more content is being shot in higher resolution and video streaming services such as Netflix offer a plethora of 4K content to choose from.

Besides the resolution and aspect ratios, the curvature of the monitor also affects your viewing experience. Learn about the differences between a flat-screen or curved panel here. Or discover a variety of monitors for different needs from ViewSonic here.

Looking for a specific TFT resolution? We offer LCD TFTs varying in resolution from 128x160 pixels to 800x480 pixels. Many of our TFT LCDs also have carrier boards to make integrating them into your product as simple as possible. All of our TFT LCDs offer full color RGB. If you"re not finding the correct TFT LCD for your product or project, please contact our support team to see if they can help you find an appropriate TFT display module for you.

For screen sizes (typically in inches, measured on the diagonal), see Display size. For a list of particular display resolutions, see Graphics display resolution.

This chart shows the most common display resolutions, with the color of each resolution type indicating the display ratio (e.g. red indicates a 4:3 ratio).

The display resolution or display modes of a digital television, computer monitor or display device is the number of distinct pixels in each dimension that can be displayed. It can be an ambiguous term especially as the displayed resolution is controlled by different factors in cathode ray tube (CRT) displays, flat-panel displays (including liquid-crystal displays) and projection displays using fixed picture-element (pixel) arrays.

One use of the term display resolution applies to fixed-pixel-array displays such as plasma display panels (PDP), liquid-crystal displays (LCD), Digital Light Processing (DLP) projectors, OLED displays, and similar technologies, and is simply the physical number of columns and rows of pixels creating the display (e.g. 1920 × 1080). A consequence of having a fixed-grid display is that, for multi-format video inputs, all displays need a "scaling engine" (a digital video processor that includes a memory array) to match the incoming picture format to the display.

For device displays such as phones, tablets, monitors and televisions, the use of the term display resolution as defined above is a misnomer, though common. The term display resolution is usually used to mean pixel dimensions, the maximum number of pixels in each dimension (e.g. 1920 × 1080), which does not tell anything about the pixel density of the display on which the image is actually formed: resolution properly refers to the pixel density, the number of pixels per unit distance or area, not the total number of pixels. In digital measurement, the display resolution would be given in pixels per inch (PPI). In analog measurement, if the screen is 10 inches high, then the horizontal resolution is measured across a square 10 inches wide.NTSC TVs can typically display about 340 lines of "per picture height" horizontal resolution from over-the-air sources, which is equivalent to about 440 total lines of actual picture information from left edge to right edge.

Some commentators also use display resolution to indicate a range of input formats that the display"s input electronics will accept and often include formats greater than the screen"s native grid size even though they have to be down-scaled to match the screen"s parameters (e.g. accepting a 1920 × 1080 input on a display with a native 1366 × 768 pixel array). In the case of television inputs, many manufacturers will take the input and zoom it out to "overscan" the display by as much as 5% so input resolution is not necessarily display resolution.

The eye"s perception of display resolution can be affected by a number of factors – see image resolution and optical resolution. One factor is the display screen"s rectangular shape, which is expressed as the ratio of the physical picture width to the physical picture height. This is known as the aspect ratio. A screen"s physical aspect ratio and the individual pixels" aspect ratio may not necessarily be the same. An array of 1280 × 720 on a 16:9 display has square pixels, but an array of 1024 × 768 on a 16:9 display has oblong pixels.

An example of pixel shape affecting "resolution" or perceived sharpness: displaying more information in a smaller area using a higher resolution makes the image much clearer or "sharper". However, most recent screen technologies are fixed at a certain resolution; making the resolution lower on these kinds of screens will greatly decrease sharpness, as an interpolation process is used to "fix" the non-native resolution input into the display"s native resolution output.

While some CRT-based displays may use digital video processing that involves image scaling using memory arrays, ultimately "display resolution" in CRT-type displays is affected by different parameters such as spot size and focus, astigmatic effects in the display corners, the color phosphor pitch shadow mask (such as Trinitron) in color displays, and the video bandwidth.

Most television display manufacturers "overscan" the pictures on their displays (CRTs and PDPs, LCDs etc.), so that the effective on-screen picture may be reduced from 720 × 576 (480) to 680 × 550 (450), for example. The size of the invisible area somewhat depends on the display device. Some HD televisions do this as well, to a similar extent.

Computer displays including projectors generally do not overscan although many models (particularly CRT displays) allow it. CRT displays tend to be underscanned in stock configurations, to compensate for the increasing distortions at the corners.

Interlaced video (also known as interlaced scan) is a technique for doubling the perceived frame rate of a video display without consuming extra bandwidth. The interlaced signal contains two fields of a video frame captured consecutively. This enhances motion perception to the viewer, and reduces flicker by taking advantage of the phi phenomenon.

Progressive scanning (alternatively referred to as noninterlaced scanning) is a format of displaying, storing, or transmitting moving images in which all the lines of each frame are drawn in sequence. This is in contrast to interlaced video used in traditional analog television systems where only the odd lines, then the even lines of each frame (each image called a video field) are drawn alternately, so that only half the number of actual image frames are used to produce video.

Many personal computers introduced in the late 1970s and the 1980s were designed to use television receivers as their display devices, making the resolutions dependent on the television standards in use, including PAL and NTSC. Picture sizes were usually limited to ensure the visibility of all the pixels in the major television standards and the broad range of television sets with varying amounts of over scan. The actual drawable picture area was, therefore, somewhat smaller than the whole screen, and was usually surrounded by a static-colored border (see image to right). Also, the interlace scanning was usually omitted in order to provide more stability to the picture, effectively halving the vertical resolution in progress. 160 × 200, 320 × 200 and 640 × 200 on NTSC were relatively common resolutions in the era (224, 240 or 256 scanlines were also common). In the IBM PC world, these resolutions came to be used by 16-color EGA video cards.

One of the drawbacks of using a classic television is that the computer display resolution is higher than the television could decode. Chroma resolution for NTSC/PAL televisions are bandwidth-limited to a maximum 1.5MHz, or approximately 160 pixels wide, which led to blurring of the color for 320- or 640-wide signals, and made text difficult to read (see example image below). Many users upgraded to higher-quality televisions with S-Video or RGBI inputs that helped eliminate chroma blur and produce more legible displays. The earliest, lowest cost solution to the chroma problem was offered in the Atari 2600 Video Computer System and the Apple II+, both of which offered the option to disable the color and view a legacy black-and-white signal. On the Commodore 64, the GEOS mirrored the Mac OS method of using black-and-white to improve readability.

The 640 × 400i resolution (720 × 480i with borders disabled) was first introduced by home computers such as the Commodore Amiga and, later, Atari Falcon. These computers used interlace to boost the maximum vertical resolution. These modes were only suited to graphics or gaming, as the flickering interlace made reading text in word processor, database, or spreadsheet software difficult. (Modern game consoles solve this problem by pre-filtering the 480i video to a lower resolution. For example, Final Fantasy XII suffers from flicker when the filter is turned off, but stabilizes once filtering is restored. The computers of the 1980s lacked sufficient power to run similar filtering software.)

In the PC world, the IBM PS/2 VGA (multi-color) on-board graphics chips used a non-interlaced (progressive) 640 × 480 × 16 color resolution that was easier to read and thus more useful for office work. It was the standard resolution from 1990 to around 1996.800 × 600 until around 2000. Microsoft Windows XP, released in 2001, was designed to run at 800 × 600 minimum, although it is possible to select the original 640 × 480 in the Advanced Settings window.

Programs designed to mimic older hardware such as Atari, Sega, or Nintendo game consoles (emulators) when attached to multiscan CRTs, routinely use much lower resolutions, such as 160 × 200 or 320 × 400 for greater authenticity, though other emulators have taken advantage of pixelation recognition on circle, square, triangle and other geometric features on a lesser resolution for a more scaled vector rendering. Some emulators, at higher resolutions, can even mimic the aperture grille and shadow masks of CRT monitors.

In 2002, 1024 × 768 eXtended Graphics Array was the most common display resolution. Many web sites and multimedia products were re-designed from the previous 800 × 600 format to the layouts optimized for 1024 × 768.

The availability of inexpensive LCD monitors made the 5∶4 aspect ratio resolution of 1280 × 1024 more popular for desktop usage during the first decade of the 21st century. Many computer users including CAD users, graphic artists and video game players ran their computers at 1600 × 1200 resolution (UXGA) or higher such as 2048 × 1536 QXGA if they had the necessary equipment. Other available resolutions included oversize aspects like 1400 × 1050 SXGA+ and wide aspects like 1280 × 800 WXGA, 1440 × 900 WXGA+, 1680 × 1050 WSXGA+, and 1920 × 1200 WUXGA; monitors built to the 720p and 1080p standard were also not unusual among home media and video game players, due to the perfect screen compatibility with movie and video game releases. A new more-than-HD resolution of 2560 × 1600 WQXGA was released in 30-inch LCD monitors in 2007.

In 2010, 27-inch LCD monitors with the 2560 × 1440 resolution were released by multiple manufacturers, and in 2012, Apple introduced a 2880 × 1800 display on the MacBook Pro. Panels for professional environments, such as medical use and air traffic control, support resolutions up to 4096 × 21602048 × 2048 pixels).

The following table lists the usage share of display resolutions from two sources, as of June 2020. The numbers are not representative of computer users in general.

In recent years the 16:9 aspect ratio has become more common in notebook displays. 1366 × 768 (HD) has become popular for most low-cost notebooks, while 1920 × 1080 (FHD) and higher resolutions are available for more premium notebooks.

When a computer display resolution is set higher than the physical screen resolution (native resolution), some video drivers make the virtual screen scrollable over the physical screen thus realizing a two dimensional virtual desktop with its viewport. Most LCD manufacturers do make note of the panel"s native resolution as working in a non-native resolution on LCDs will result in a poorer image, due to dropping of pixels to make the image fit (when using DVI) or insufficient sampling of the analog signal (when using VGA connector). Few CRT manufacturers will quote the true native resolution, because CRTs are analog in nature and can vary their display from as low as 320 × 200 (emulation of older computers or game consoles) to as high as the internal board will allow, or the image becomes too detailed for the vacuum tube to recreate (i.e., analog blur). Thus, CRTs provide a variability in resolution that fixed resolution LCDs cannot provide.

As far as digital cinematography is concerned, video resolution standards depend first on the frames" aspect ratio in the film stock (which is usually scanned for digital intermediate post-production) and then on the actual points" count. Although there is not a unique set of standardized sizes, it is commonplace within the motion picture industry to refer to "nK" image "quality", where n is a (small, usually even) integer number which translates into a set of actual resolutions, depending on the film format. As a reference consider that, for a 4:3 (around 1.33:1) aspect ratio which a film frame (no matter what is its format) is expected to horizontally fit in, n is the multiplier of 1024 such that the horizontal resolution is exactly 1024•n points.2048 × 1536 pixels, whereas 4K reference resolution is 4096 × 3072 pixels. Nevertheless, 2K may also refer to resolutions like 2048 × 1556 (full-aperture), 2048 × 1152 (HDTV, 16:9 aspect ratio) or 2048 × 872 pixels (Cinemascope, 2.35:1 aspect ratio). It is also worth noting that while a frame resolution may be, for example, 3:2 (720 × 480 NTSC), that is not what you will see on-screen (i.e. 4:3 or 16:9 depending on the intended aspect ratio of the original material).

Find the native resolution of your monitor. Knowing the native resolution of your monitor will help you quickly get the clearest image. In Windows 7, 8, and most versions OS X, the recommended resolution will be labeled. Below are some common resolutions for monitors:

Select your active display (if necessary). Select the display that you want to check the resolution for. Click the Identify button to display numbers on each of your screens so that you can select the right one.

Check if the current resolution says "Recommended". The Recommended resolution is the native resolution of your monitor. Selecting this will result in the clearest image.

Change your resolution using the slider. Clicking the "Resolution" drop-down menu in Windows 7 and 8 will display the slider. Drag the slider to change the display resolution on your monitor. Resolutions other than the recommended one will result in a blurry, stretched, or squished image.

Click the Apple menu and select "System Preferences". By default, OS X will choose the native resolution for your display, giving you in the clearest image. You can change this if a program calls for a certain resolution or you need to adjust the size of objects on your screen.

Select the "Scaled" option to change your resolution. By default, the "Best for display" option will be selected. This will set the display at your monitor"s native resolution. Select "Scaled" if you want to choose a different option.

Creating an array of the best LCD Monitors for Stock Traders is one of the many ways you can make money on your PC. Unlike gaming rigs which require high-speed refresh rates and response times, you will only need clarity and a perfectly sized display to cater to your needs. This niche can involve a lot of different software at any given time, so your best bet is probably a multi-display machine.  You want a set up that allows you scan multiple markets at the same time, decreases eye fatigue, offers high resolution, maximizes speed and keeps costs down.  The setups below are more affordable and responsive than your standard Bloomberg terminal monitor.  Users of TradeStation, Thinkorswim, and eSignal will benefit from the expansive real estate of a multi-monitor setup.

Although newer and more efficient apps now use widget-styled interfaces, your best bet could be a singular, large monitor with a QHD or UHD resolution. In any case, the wide market can provide you with a specific solution which should fit your budget and satisfy your meticulous requirements.

Setting up a command center-styled system can get tricky or expensive, but there are practical solutions you can easily purchase and build yourself. Determining how many displays you will require maximizing efficiency and productivity is key.

However, if your stock market business runs several windows which monitor different markets, clients, brokers or you just need the extra viewing space, you can opt to utilize a mounting mechanism which can hold up to six different displays

The cheapest solution we can find and recommend is the VIVO Hex LCD Monitor Stand, which can hold up to six 24-inch monitors via their 75 x 75 or 100 x 100 VESA mounting holes. This mechanism is made of high-grade steel and aluminum for durability.

Each arm will provide -15 to +15 degrees of tilt, and 360 degrees of swivel and pivot, giving you absolute control over how you would want to position each screen to get the perfect view angle. You also won’t need to worry about messy wires, since the VIVO Hex LCD Monitor Stand also includes an integrated cable management system.

The next step is choosing acceptable models from the plethora of monitors being sold. We recommend users to get IPS-equipped models so you won’t have to deal with color shifts and poor viewing angles. We also recommend 22-inch to 24-inch models with a 1080p resolution since the recommended mount can only hold such.

Dell is a staple brand when considering professional or business monitors for their outstanding reliability, performance, and sophisticated design. The Dell S2415H is one such model who embodies these qualities, despite having an awesomely affordable price. Clad in the company’s signature matte black and silver cabinets, this borderless display will look fantastic on the mount we specified.

For this category, we recommend users to get either a large 4K display or a stunning ultra-wide monitor with a UW-QHD resolution so you can maximize your virtual viewing space for your widgets and apps.

The Dell P43127Q is one of the most specialized monitors for stock trading because it is a multi-client display. The massive 43-inch screen with a 4K panel can split into four different sections with 1080p resolutions each, giving users a simulated quad monitor experience for unrivaled efficiency.

You can utilize several host devices to stream multiple sources in the Dell P4317Q, or you can utilize the massive viewing space to open your widgets and designate them to a side or quadrant freely. The gorgeous 10-bit IPS panel can display near perfect coverage of the sRGB gamut, and panel uniformity is excellent for something so big.

Another excellent behemoth is the Philips BDM4350UC, a 43-inch professional monitor with an IPS panel. This model almost looks like your 4K TV in the living room with thin bezels, making it look like a gorgeous centerpiece for your office or workspace. Just like the Del P4317Q above, this screen can also serve as a multi-client device. The 4K resolution of the big screen also enables you to open multiple apps and widgets simultaneously, ensuring your workflow is efficient.

The Philips BDM4350UC carries a high-quality IPS panel with eye-popping color and detail, plus our review unit did not display any severe backlight bleeding or poor uniformity, which is quite rare for big screens. This option is excellent for designing and movies, and we can’t imagine why it shouldn’t be included as one of the best monitors for stock trading.

If you want something bigger and better than the previous entry, the next best thing is the LG 38UC99 which has a whopping 3840 x 1600 resolution which is enough to display three or four windows side by side. Like most of LG’s high-end monitors, the 38UC99 is able to output 99% sRGB coverage for excellent vibrancy and accuracy.

Resolution is an important indicator of a 7-inch LCD screen, and it often represents an important indicator of the quality of the 7-inch LCD screen. Do you really understand the 7-inch LCD screen resolution? Did you know that you can also learn other information about the 7-inch LCD screen from the resolution? Today Proculus will share with you about it.

How to judge horizontal screen and vertical screen from the resolution? In fact, it is very simple, for example, 720*1280, the front number 720 is smaller than the back number 1280, then this situation is vertical screen. And 1280*720 means that the number behind is smaller than the number in front, it is horizontal screen.

This is very easy to understand, that is, the higher the resolution, the better the display effect, and the more pixels, the richer the displayed colors. Common 7-inch LCD screens have high resolutions of 720*1280, 1024*600 and so on.

Anyone who knows the industry of 7-inch LCD screens must have heard of the aspect ratio. For example, the aspect ratio of a 7-inch LCD screen with a resolution of 1024*600 is a 16:9 display screen. How is this calculated? You can search the formula on the Internet and apply it directly, that is, the result obtained by dividing the resolution is which 7 inch LCD screen is a few ratios. For example, what is the ratio of 1280*800 to a 7-inch LCD screen? 1280/800=1.6, 16:10=1.6666. Then the 7in LCD screen with a resolution of 1280*800 is 16:10.

After reading the above knowledge, do you understand? From the resolution of the 7-inch LCD screen, you can not only know the display effect of the 7-inch LCD screen, but also know that it is a landscape/portrait screen, and know the aspect ratio of this screen.

Suzhou Proculus Technologies Co., Ltd. is a national high-tech enterprise integrating R&D, design, production and sales. As a custom LCD and screen display manufacturer, we can provide you with custom LCD displays, screens and panels according to your needs. Now, we are focusing on developing the world market and eager to provide quality products and services to customers from all over the world!

RF2H89M17–Electronic components on circuit board with printed multi wire connections in assembly with bent flexible part. Plastic FPC interface for a LCD device.

RF2BJCH2Y–Windows XP start menu bar, windows logo on an old low resolution lcd display, closeup, pixels visible. Old windows operating system distribution

RF2G8A3MY–Printed circuit board connected by flexible flat cable to LCD panel. Closeup of electronic components - micro chip, inductor or capacitor on green PCB.

RF2C8FY7G–05.07.19 - Austria: Closeup photo of the interior of the brown open-pore ash wood trim on the center console, radio, AC, LCD screen luxury car

RF2E2367W–Green flexible circuit board floating on black background. Small bent plastic flex PCB for signals transmission in LCD screens of electronic devices.

RFHTTN13–Closeup RGB led diode of led TV or led monitor screen display panel. Colorful led screen background for design with copy space for text or image

RF2HJ8560–Image of donuts and a glass of milk top view in a lcd Screen of a DSLR or Mirrorless camera with rim light on top, concept of food photography

RF2FD5N9H–Modern DSLR with touch display, featuring BSI CMOS sensor with no optical low pass filter with Expeed 5 processor, build with an extremely durable rug

RFHMX4HE–BATH, UK - SEPTEMBER 12, 2015: Close-up of the Google.com search homepage displayed on a LCD computer screen with the silhouette of a man"s head out o

RF2K52H8A–Old LCD color TV screen black and white noise grain up close, detail. Lost signal, interrupted broadcast end simple abstract concept, background textu

RFHNF2MP–BATH, UK - SEPTEMBER 14, 2015: Close-up of the Ebay homepage displayed on a LCD computer screen with the silhouette of a man"s head out of focus in t

RF2C92RK8–A silver laptop with a broken keyboard, tablet with a cracked display and black phone. A close-up picture of part of broken laptop and cracked screen

Many Apple products use liquid crystal displays (LCD). LCD technology uses rows and columns of addressable points (pixels) that render text and images on the screen. Each pixel has three separate subpixels—red, green and blue—that allow an image to render in full color. Each subpixel has a corresponding transistor responsible for turning that subpixel on and off.

Depending on the display size, there can be thousands or millions of subpixels on the LCD panel. For example, the LCD panel used in the iMac (Retina 5K, 27-inch, 2019) has a display resolution of 5120 x 2880, which means there are over 14.7 million pixels. Each pixel is made up of a red, a green, and a blue subpixel, resulting in over 44 million individual picture elements on the 27-inch display. Occasionally, a transistor may not work perfectly, which results in the affected subpixel remaining off (dark) or on (bright). With the millions of subpixels on a display, it is possible to have a low number of such transistors on an LCD. In some cases a small piece of dust or other foreign material may appear to be a pixel anomaly. Apple strives to use the highest quality LCD panels in its products, however pixel anomalies can occur in a small percentage of panels.

In many cases pixel anomalies are caused by a piece of foreign material that is trapped somewhere in the display or on the front surface of the glass panel. Foreign material is typically irregular in shape and is usually most noticeable when viewed against a white background. Foreign material that is on the front surface of the glass panel can be easily removed using a lint free cloth. Foreign material that is trapped within the screen must be removed by an Apple Authorized Service Provider or Apple Retail Store.

If you are concerned about pixel anomalies on your display, take your Apple product in for closer examination at an Apple Store, Apple Authorized Service Provider, or an Independent Repair Provider. There may be a charge for the evaluation. Genuine Apple parts are also available for out-of-warranty repairs through Self Service Repair.*

Find Display resolution, and then choose an option. It"s usually best to stick with the one that"s marked (Recommended). Monitors can support resolutions that are lower than their native resolutions, but text won"t look as sharp and the display might be small, centered on the screen, edged with black, or stretched.

Note:If you see unexpected changes in your screen resolution, your graphics driver might need to be updated. To see and install available updates, select Start >Settings > Update & Security > Windows Update.

Screen resolution is crucial for designers, photographers and artists. When you"re working on digital creations, your monitor is one of the most important tools you own since it shows you what"s happening while you work as well as the final result.

The screen resolution of your monitor can have a huge impact on how your work is displayed, and on how comfortably you can work without straining your eyes, so it"s important to know what screen resolution your monitor has, and what screen resolution to choose when you"re upgrading your kit.

If your screen resolution is too high, icons and texts may appear too small and your hardware may be put under additional strain as the monitor struggles to hit the high resolutions. But if your screen resolution is set too low, it can result in poor image quality that takes up too much workspace and can also harm the results of your work.

In this guide, we"ll explain why screen resolution is so important for designers and how it can affect your results, how to check the screen resolution of your current monitor, and how to buy the best monitor for your needs

What do we mean when we talk about screen resolution? The monitor that"s connected to your PC – or built into your laptop – displays images using pixels, which are essentially small squares of light that change colour. Computer screens are made up of thousands of pixels. By changing the colours of those pixels in certain patterns, screens can show images, photos, text and all kinds of graphics.

The numbers that we use when we talk about screen resolution are the number of pixels a screen can show horizontally and vertically. A screen that has a resolution of 1920 x 1080 (a popular resolution often known as 1080p or Full HD), can display 1,080 pixels vertically, and 1,920 pixels horizontally.

The higher the number of pixels a screen can show, the sharper and more detailed the image quality. But, the number of pixels that a screen can show isn"t the only factor involved when it comes to image quality. There"s also pixel density. Monitors come in all kinds of sizes, as well as resolutions. You"ll often find monitors of different sizes that have the same number of pixels, for example a 24-inch monitor and a 32-inch monitor both with a screen resolution of 1920 x 1080. The image quality on the smaller monitor can often look sharper and more vivid because of its pixel density. This is measured in PPI (Pixels Per Inch). The smaller screen will have a higher number of pixels per inch than the larger screen.

The higher the PPI, the better the image quality, so while it might be tempting to choose the largest screen possible, if you"re looking for the best image quality, consider getting a smaller monitor with a higher resolution rather than a larger monitor with a lower resolution.

It"s worth bearing in mind that the screen resolution that your monitor advertises isn"t the only resolution it can display. The published resolution is known as the native resolution of the screen and is the resolution that looks best on the display. You can change the resolution of the screen, although you can only change it to a lower resolution than the native resolution, not higher.

For example, if you buy a 4K (also known as an Ultra High Definition) screen, with a resolution of 3840 x 2160, and you find the resolution is too high, you can set your PC, Mac or laptop to display at a lower resolution, for example 1920 x 1080.

If you want to check the native resolution of your monitor or laptop screen, the process is pretty easy, although it differs depending on whether you use a Windows machine or a Mac or MacBook.

If you use Windows on your PC or laptop, you can check the screen resolution (and change it) by right-clicking on an empty space on the desktop and clicking "Display settings".

In the window that opens, you"ll see "Display resolution" with the current resolution listed underneath. If it says "(Recommended)" next to the resolution, that means it"s the native resolution for your display and the one that will probably look the best.

If you want to change the screen resolution, click the down arrow next to the resolution. This will show a list of all the other display resolutions your screen can handle. Click one, and the resolution will be applied – temporarily at least.

Because changing the resolution to something that your screen doesn"t support can cause problems, Windows will show you what the resolution looks like and ask you if you want to keep it. If you do, click "Keep changes". Otherwise, click "Revert" to change the resolution back to what it was before. You can also choose to do nothing, and after 15 seconds your device will revert to the previous resolution. This is useful if you accidentally choose a resolution that your display can"t handle, leading to it displaying a blank screen. Simply wait 15 seconds, and the old resolution will come back.

The easiest way to find the display resolution on your Mac or MacBook is to click the Apple icon in the top left-hand corner of the screen. On the menu that appears, select "About This Mac". A window will pop up, and at the top you"ll see "Displays." Click there, and you"ll see the size and resolution of your screen.

To change the display resolution on your Mac"s screen, click on "Displays Preferences" in the bottom right-hand corner of the open window. In the new window that pops up, select "Scaled" next to where it says "Resolution". Choose the resolution based on whether you want larger text or more space.

So, what screen resolution should you go for? The answer to that question varies depending on the sort of work you"ll be doing and what kind of machine you"ll be working on.

Let"s start with the kind of work. If you"re a graphic artist or 3D modeller, then the minimum resolution you should opt for is 1360 x 768. However, if you can, we recommend going for 1920 x 1080. That extra resolution will give you a bigger canvas to work on, and it will improve the image quality.

For people working with complex 3D models, such as architects, animators or game developers, going above 1920 x 1080 can begin to put a real strain on your machine"s GPU (Graphics Processing Unit). If you want to go for a higher resolution, make sure your hardware can handle it, otherwise you may find your PC performs very slowly when trying to render at those high resolutions.

For video editors, we recommend 1920 x 1080 as a minimum. This is because 1080p is the standard high-definition resolution for videos, so if you"re working with 1080p video, you"ll want a screen that can display that natively. If you work with 4K video, then go for a screen resolution of 3840 x 2160 since this will allow you to play back 4K footage natively.

For photographers, we"d recommend going for the highest resolution you can afford. Still images don"t require as much graphical grunt to display on high-resolution screens, and most photographs are taken at well above 1080p resolutions. For example, a camera that takes 21-megapixel photos is actually capturing images at 5,104 x 4,092 resolution. Even a 4K monitor won"t display that natively, but the higher the resolution of the screen, the better (and more accurately) your photos will appear.

The resolutions we mention above apply to standard widescreen monitors with a 16:9 aspect ratio. However, some devices have different aspect ratios – and therefore different display resolutions.

For example, the 15-inch MacBook Pro has a 2,880 x 1,800 resolution screen. That makes it a lot sharper than a standard 1080p display. Meanwhile, the Surface Laptop 3(opens in new tab) has a 15-inch display with a 3:2 aspect ratio and 2,496 x 1,664 resolution. Again, that makes it a better display than a standard 1080p screen, though not quite as sharp as the screen on the MacBook Pro.

Other excellent laptops with high screen resolutions recommended for digital creatives include the Surface Book 2(opens in new tab) (with a 3,240 x 2,160 resolution), the Dell XPS 15(opens in new tab), which comes with either a 2,560 x 1,080 screen, or a 3,840 x 2,160 display.

Check out our pick of the best laptops for graphic design(opens in new tab) for more great laptops with high-resolution screens.The best deals on 4k monitors