lcd display dimensions quotation

Liquid crystal display (LCD) is a flat panel display that uses the light modulating properties of liquid crystals. Liquid crystals do not produce light directly, instead using a backlight or reflector to produce images in colour or monochrome.

The Displaytech 162M series is a lineup of our largest 16x2 character LCD modules. These modules have a 122x44 mm outer dimension with 99x24 mm viewing area on the display. The 162M 16x2 LCD displays are available in STN or FSTN LCD modes with or without an LED backlight. The backlight color options include yellow green, white, blue, pure green, or amber color. Get a free quote direct from Displaytech for a 16x2 character LCD display from the 162M series.

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.

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.

1. We’re interesting in Embedded Display: ENHANCEMENT OF NEW TFT LCDS EQUIPPED WITH EMBEDDED DISPLAY PORT INTERFACE 11.6” – 15.6” – 18.5” – 30”. We would like to order 1 unit for testing and checking if it’s suitable for our needs. Please submit your best price & delivery time. Appreciate to have your soonest reply.

2. Hello, Hope this message finds you well. We are looking for a display that meets the following requirements: Diagonal Size 10.1” (256.5mm), Resolution – Higher than 1280x800, Max thickness 8mm. Annual quantity needed is 10,000/year, Ideal voltage is 24V, Production parts guaranteed to be available for 10 years, Connector interface: eDP. Would you recoment this display? -- TFT Color Display 10.1inch 1920X1200 resolution in Medical system. What is the pricing / lead time for an order of Quantity 100 & 10,000? Thank you for your help

4. Dear Sir/madam, We are interested in two displays that you have listed on your website. Could we please arrange to order one of each for our engineering team to test with them. Regards

5. Hello, My coworker had worked in past with you with regards to the 3.46" 800*340 resolution display. We really liked the samples and I am looking to know more about that display. I also wanted to know if you have a 3.46" 400*170 resolution display as the 800*340 is a bit of overkill for our application. Thank you

11. Hi, I am interested in the above product, but need transflective display. It must be able to be read in sunlight with the backlight off. We are seeking quantity about 5,000 per year. Can you provide this? Thank you

We offer character LCDs and graphic LCDs as modules or COG (Chip On Glass) displays in a wide array of character and pixel configuration sizes. From yellow/green, red, orange, green, blue, amber, white, and RGB backlight colors to displays without a backlight, we have the perfect LCD for your application.

3.30” 128 x 64 Graphic Display The G-12864R4G-VA is a 3.30” 128 x 64 Monochrome LCD Display with a module size of 96.0 x 60.5 x 14.0 and an active area of 72.9 x 40.9. The G-12864R4G-VA 128 x 64 display uses Super Twisted Nematic or Film Compensated Super Twisted Nematic glass with LED backlighting and a reflective, transflective, or transmissive display. View Additional Details Generic Part G-12864R4G-VA Display Format 128 x 64 Graphic Display Module Size 96.0 x 60.5 x 14.0 Diagonal 3.30 Active Area 72.9 x 40.9 Pixel Pitch 0.570 x 0.640 Backlight LED Display Type R,TF,TM Glass…

192 x 64 3.30” Graphic Display The G-1926415C-VA is a 3.30” 192 x 64 Monochrome LCD Display with a module size of 100.0 x 60.0 x 12.0 and an active area of 78.68 x 26.2. The G-1926415C-VA 192 x 64 display uses Super Twisted Nematic or Film Compensated Super Twisted Nematic glass with LED backlighting and a reflective, transflective, or transmissive display. View Additional Details Generic Part G-1926415C-VA Display Format 192 x 64 Graphic Display Module Size 100.0 x 60.0 x 12.0 Diagonal 3.30 Active Area 78.68 x 26.2 Pixel Pitch 0.410 x 0.410 Backlight…

3.30” 192 x 64 Graphic Display The G-1926419G-VA is a 3.30” 192 x 64 Monochrome LCD Display with a module size of 104.0 x 44.0 x 8.1 and an active area of 78.67 x 26.19. The G-1926419G-VA 192 x 64 display uses Super Twisted Nematic or Film Compensated Super Twisted Nematic glass with LED backlighting and a reflective, transflective, or transmissive display. View Additional Details Generic Part G-1926419G-VA Display Format 192 x 64 Graphic Display Module Size 104.0 x 44.0 x 8.1 Diagonal 3.30 Active Area 78.67 x 26.19 Pixel Pitch 0.410 x 0.410 Backlight…

3.30” 240 x 64 Graphic Display The G-2406407C-VA is a 3.30” 240 x 64 Monochrome LCD Display with a module size of 10.0 x 50.0 x 10.5 and an active area of 81.57 x 23.65. The G-2406407C-VA 240 x 64 display uses Super Twisted Nematic or Film Compensated Super Twisted Nematic glass with LED backlighting and a reflective, transflective, or transmissive display. View Additional Details Generic Part G-2406407C-VA Display Format 240 x 64 Graphic Display Module Size 100.0 x 50.0 x 10.5 Diagonal 3.30 Active Area 81.57 x 23.65 Pixel Pitch 0.340 x 0.370 Backlight…

3.40” 160 x 240 Graphic Display The G-16024001G-VA is a 3.40” 160 x 240 Monochrome LCD Display with a module size of 85.0 x 61.0 x 2.7 and an active area of 47.9 x 71.9. The G-16024001G-VA 160 x 240 display uses Super Twisted Nematic or Film Compensated Super Twisted Nematic glass with Electro Luminescent backlighting and a reflective, transflective, or transmissive display. View Additional Details Generic Part G-16024001G-VA Display Format 160 x 240 Graphic Display Module Size 85.0 x 61.0 x 2.7 Diagonal 3.40 Active Area 47.9 x 71.9 Pixel Pitch 0.300 x 0.300…

3.5 ” 340 x 240 Mono TFT Display The PDI-24032052G(R) is a small-size 3.5” Mono TFT with a 320 x 240 resolution. This product offers improved contrast, viewing angle, brightness and response time over traditional passive monochrome products. View Additional Details Part Number PDI-24032052G(R) Format 320 X 240 Module Size 58.56mm x 79.94mm x 1.6mm Active Area 53.28mm x 71.04mm Diagonal 3.5 Display Type Negative Transmissive Brightness N/A Touch Panel N/A 1.0 DIMENSIONAL DRAWING – FRONT PDI-24032052G(R) was last modified: May 21st, 2021 by kkyang

3.50” 128 x 128 Graphic Display The G-12812827C-VA is a 3.50” 128 x 128 Monochrome LCD Display with a module size of 86.0 x 95.0 x 10.0 and an active area of 62.69 x 62.69. The G-12812827C-VA 128 x 128 display uses Super Twisted Nematic or Film Compensated Super Twisted Nematic glass with LED backlighting and a reflective, transflective, or transmissive display. View Additional Details Generic Part G-12812827C-VA Display Format 128 x 128 Graphic Display Module Size 86.0 x 95.0 x 10.0 Diagonal 3.50 Active Area 62.69 x 62.69 Pixel Pitch 0.490 x 0.490 Backlight…

3.50” 240 x 160 Graphic Display The G-24016015T-VA is a 3.50” 240 x 160 Monochrome LCD Display with a module size of 95.0 x 67.0 x 2.8 and an active area of 74.38 x 49.58. The G-24016015T-VA 240 x 160 display uses Super Twisted Nematic or Film Compensated Super Twisted Nematic glass with no backlighting and a reflective, transflective, or transmissive display. View Additional Details Generic Part G-24016015T-VA Display Format 240 x 160 Graphic Display Module Size 95.0 x 67.0 x 2.8 Diagonal 3.50 Active Area 74.38 x 49.58 Pixel Pitch 0.310 x 0.310 Backlight No…

3.5″ 320 x 240 TFT COLOR LCD Phoenix Display International PDI035QVIH-28B is a small-size 3.5” color TFT liquid crystal display (LCD) with a module size of 76.75 x 63.7 x 3.27 mm and active area of 70.08 x 52.56 mm. This product is a-Si TFT, Positive, Transmissive glass with a 262K color  320  x 240 resolution. Its brightness is 350 nits with a contrast ratio of 300. Using an HX8238-D driver with a RGB interface and a Ziff style interconnect. This product offers improved contrast, color saturation and response time. Similar product(s): None. All our…

3.5″  320 x RGB x 480  Transmissive Color TFT Display Phoenix Display International PDI035HVSI-31 is a small-size 3.5” color TFT liquid crystal display (LCD) with a module size of 54.48 * 84.71 * 2.3 mm, and active area 48.96 * 73.44 mm. This product is a-Si TFT, Normally White, Transmissive glass with a 320 * RGB * 480 resolution. Its brightness is 320 nits with a contrast ratio of 500. Using an ILI9488 driver with a 3SPI+RGS18-bit interface and a zero insertion force (ZIF) type flex interconnect. This product offers improved contrast , color saturation…

3.5″ 320 x (RGB) x 480 Transmissive Color TFT Display Phoenix Display International PDI035HVHI-48 is a small-size 3.5” color TFT liquid crystal display (LCD) with a module size of 53.76* 84.18 * 2.1 mm, and active area 48.96 * 73.44 mm. This product is a-Si TFT, Normally White, Transmissive glass with a 320 * RGB * 480 resolution. Its brightness is 350 nits with a contrast ratio of 800. Using a ILI9488 driver with a 3SPI+RGB18-bit interface and a zero insertion force (ZIF) type flex interconnect. This product offers improved contrast , color saturation and…

3.5″ 320 x (RGB) x 800 Bar Type TFT Color LCD Phoenix Display International PDI035WVBS-51 is a small-size bar type 3.5” color TFT liquid crystal display (LCD) with a module size of 40.97 * 94.4 * 2.78 mm, and active area 33.96 * 81 mm. This product is a-Si TFT, Normally White, Transmissive glass with a 340 * RGB * 800 resolution. Its brightness is 330 nits with a contrast ratio of 600. Using a ST7701S driver with a RGB interface and a zero insertion force (ZIF) type flex interconnect. This product offers improved contrast…

3.60” 240 x 128 Graphic Display The G-24012803T-VA is a 3.60” 240 x 128 Monochrome LCD Display with a module size of 94.1 x 58.5 x 3.0 and an active area of 81.57 x 40.93. The G-24012803T-VA 240 x 128 display uses Super Twisted Nematic or Film Compensated Super Twisted Nematic glass with no backlighting and a reflective, transflective, or transmissive display. View Additional Details Generic Part G-24012803T-VA Display Format 240 x 128 Graphic Display Module Size 94.1 x 58.5 x 3.0 Diagonal 3.60 Active Area 81.57 x 40.93 Pixel Pitch 0.340 x 0.320 Backlight…

The three 14-inch landscape flight displays can function independently as a primary flight display (PFD) or multifunction display (MFD). The displays also function in multi-pane mode, the center pedestal for MFD control and two additional panels control each PFD. Pilots can customize displays via the touchscreen control panels, organizing and prioritizing the flight data presented.

In this tutorial, I’ll explain how to set up an LCD on an Arduino and show you all the different ways you can program it. I’ll show you how to print text, scroll text, make custom characters, blink text, and position text. They’re great for any project that outputs data, and they can make your project a lot more interesting and interactive.

The display I’m using is a 16×2 LCD display that I bought for about $5. You may be wondering why it’s called a 16×2 LCD. The part 16×2 means that the LCD has 2 lines, and can display 16 characters per line. Therefore, a 16×2 LCD screen can display up to 32 characters at once. It is possible to display more than 32 characters with scrolling though.

The code in this article is written for LCD’s that use the standard Hitachi HD44780 driver. If your LCD has 16 pins, then it probably has the Hitachi HD44780 driver. These displays can be wired in either 4 bit mode or 8 bit mode. Wiring the LCD in 4 bit mode is usually preferred since it uses four less wires than 8 bit mode. In practice, there isn’t a noticeable difference in performance between the two modes. In this tutorial, I’ll connect the LCD in 4 bit mode.

Here’s a diagram of the pins on the LCD I’m using. The connections from each pin to the Arduino will be the same, but your pins might be arranged differently on the LCD. Be sure to check the datasheet or look for labels on your particular LCD:

Also, you might need to solder a 16 pin header to your LCD before connecting it to a breadboard. Follow the diagram below to wire the LCD to your Arduino:

There are 19 different functions in the LiquidCrystal library available for us to use. These functions do things like change the position of the text, move text across the screen, or make the display turn on or off. What follows is a short description of each function, and how to use it in a program.

TheLiquidCrystal() function sets the pins the Arduino uses to connect to the LCD. You can use any of the Arduino’s digital pins to control the LCD. Just put the Arduino pin numbers inside the parentheses in this order:

This function sets the dimensions of the LCD. It needs to be placed before any other LiquidCrystal function in the void setup() section of the program. The number of rows and columns are specified as lcd.begin(columns, rows). For a 16×2 LCD, you would use lcd.begin(16, 2), and for a 20×4 LCD you would use lcd.begin(20, 4).

This function clears any text or data already displayed on the LCD. If you use lcd.clear() with lcd.print() and the delay() function in the void loop() section, you can make a simple blinking text program:

Similar, but more useful than lcd.home() is lcd.setCursor(). This function places the cursor (and any printed text) at any position on the screen. It can be used in the void setup() or void loop() section of your program.

The cursor position is defined with lcd.setCursor(column, row). The column and row coordinates start from zero (0-15 and 0-1 respectively). For example, using lcd.setCursor(2, 1) in the void setup() section of the “hello, world!” program above prints “hello, world!” to the lower line and shifts it to the right two spaces:

You can use this function to write different types of data to the LCD, for example the reading from a temperature sensor, or the coordinates from a GPS module. You can also use it to print custom characters that you create yourself (more on this below). Use lcd.write() in the void setup() or void loop() section of your program.

The function lcd.noCursor() turns the cursor off. lcd.cursor() and lcd.noCursor() can be used together in the void loop() section to make a blinking cursor similar to what you see in many text input fields:

Cursors can be placed anywhere on the screen with the lcd.setCursor() function. This code places a blinking cursor directly below the exclamation point in “hello, world!”:

This function creates a block style cursor that blinks on and off at approximately 500 milliseconds per cycle. Use it in the void loop() section. The function lcd.noBlink() disables the blinking block cursor.

This function turns on any text or cursors that have been printed to the LCD screen. The function lcd.noDisplay() turns off any text or cursors printed to the LCD, without clearing it from the LCD’s memory.

This function takes anything printed to the LCD and moves it to the left. It should be used in the void loop() section with a delay command following it. The function will move the text 40 spaces to the left before it loops back to the first character. This code moves the “hello, world!” text to the left, at a rate of one second per character:

Like the lcd.scrollDisplay() functions, the text can be up to 40 characters in length before repeating. At first glance, this function seems less useful than the lcd.scrollDisplay() functions, but it can be very useful for creating animations with custom characters.

lcd.noAutoscroll() turns the lcd.autoscroll() function off. Use this function before or after lcd.autoscroll() in the void loop() section to create sequences of scrolling text or animations.

This function sets the direction that text is printed to the screen. The default mode is from left to right using the command lcd.leftToRight(), but you may find some cases where it’s useful to output text in the reverse direction:

This code prints the “hello, world!” text as “!dlrow ,olleh”. Unless you specify the placement of the cursor with lcd.setCursor(), the text will print from the (0, 1) position and only the first character of the string will be visible.

This command allows you to create your own custom characters. Each character of a 16×2 LCD has a 5 pixel width and an 8 pixel height. Up to 8 different custom characters can be defined in a single program. To design your own characters, you’ll need to make a binary matrix of your custom character from an LCD character generator or map it yourself. This code creates a degree symbol (°):

Our full line of Rugged Military Displays are designed and tested to meet a wide variety of harsh environments. Our line of Military Displays all feature several standard environmental qualifications as required by application. Our standard environmental qualifications include shock, vibration, sand & dust, EMI, drip-proof, and extended operating temperatures.

5.2. COMPANIES THAT HAVE ADVERTISEMENTS DISPLAYED ON THE WEBSITE WILL STORE AND USE COOKIES IN ACCORDANCE WITH THEIR OWN PRIVACY POLICIES. ADVERTISERS AND THIRD PARTY COMPANIES WILL NOT BE PERMITTED TO ACCESS OR USE COOKIES OWNED BY THE WEBSITE.

Samsung’s new QBR series displays cut through the clutter to deliver best-in-class UHD resolution as well as intelligent UHD upscaling and rich flawless colors with Dynamic Crystal Color all in a slim design.

The QBR series features Dynamic Crystal Display, using 10 bit processing for flawless color expression, allowing viewers to enjoy a wider spectrum of colors up to one billion shades. HDR+ compatibility converts standard definition content to HDR quality for sharper contrast and more vivid colors.

The QBR series features an all-new symmetric design simplifying wall mounting and ensuring installation is seamless. The flat back and slim depth will ensure a display that will stand the test of time.

With QBR"s new cable guide feature, retailers are able to tuck away messy cables from view. This allows for a clean and visually-appealing shopping expeience for customers, even when the back of the display is visible.

With security provided by Knox, the displays feature Samsung Workspace which supports wireless cloud service access and control of a PC without needing a physical connection. Samsung Workspace simplifies meeting spaces while also improving security.

Built-in WiFi and Bluetooth allow for more personalized and interactive services as well as simplifying how businesses showcase content. Whether it’s to make networking simpler or enabling interactive beacon technology in-store, QBR series displays help businesses move into the future of retail.

The QBR series guarantees dependable functionality and is environmentally sustainable. Electromagnetic compatibility (EMC) class B compliant, meeting strict safety and reliability standards for operation, the displays are also registered by EPEAT, the global ecolabel for IT.

Samsung’s narrow bezel video wall features bezel–to-bezel width of 1.7mm that minimizes the visual distraction of video walls to elicit impacting imagery of products. The display produces a near-seamless picture across multiple screens without interruption, captivating and impressing customers.

Combined with a non-glare panel, the extreme narrow bezel video wall display is designed to help businesses create memorable content presentation even under ambient light. This panel evenly distributes light throughout the screen, eliminating glare while maintaining content vibrancy and accuracy.

Samsung"s video wall offers a powerful UHD viewing experience with minimal effort or additional equipment. As the first in the industry to have up to 5x5 wall configuration based on the use of DisplayPort 1.2 and HDMI ports, the display can project UHD content across multiple screens simultaneously.

Samsung’s multi-step factory calibration process tunes video walls to uniform brightness and color throughout multiple displays. In addition to rigorous factory calibration, users can also manage brightness and color uniformity with Samsung"s Color Expert Pro, a powerful free software program.

Samsung’s extreme narrow bezel video walls are engineered for long-term performance, eliminating maintenance expenses for users. The display features durable panels that offset backlight discrepancies while simultaneously protecting the display against heat and dust exposure.

Designed to maintain performance in various indoor environment conditions, Samsung"s video wall produces an engaging viewing experience with the elevated contrast ratios and brightness. With continuous 24/7 operations, the display enables vivid and reliable content delivery for every business need.

If you’re in the market to rent a video wall, you’ve probably run into all sorts of confusing info. Here’s the lowdown on LCD vs. LED video walls so you can make the right choice for your next conference, trade show, or other event.

We’re about to throw a whole lot of info at you. So let’s first take a second to remember why both LED and LCD video walls are a good investment in the first place.

The old adage, “the bigger the better,” is definitely true when it comes to AV. A video wall immediately symbolizes your company is established, and sends a subconscious message that people should take your business seriously. Video walls help you stand out, and compete with all the other businesses who are investing in splashy, eye-catching displays.

Content – Do have the resources to produce custom content for your video wall? After you finalize the size of your video wall, your AV provider can tell you the exact dimensions and resolution your content needs to be. From there, a designer or video editor can create custom video wall content — which is the most important part of any great video wall.

Meanwhile, an LCD video wall is a large surface for video or images built from many LCD screens. You’ve interacted with an LCD screen before — they’re on your laptop, TV monitor, and more. However, the LCD video wall screens are designed to run longer and have thinner edges, called bezels.

Technicians use special hardware and tools to stack the LCD screens on top of one another, and calibrate the wall so that an image shows up across every screen. Temporary LCD walls can usually only be about five screens across and five screens high.

Temporary LCD walls can be configured to be in many different sizes and shapes, both large and small, but typically don’t go larger than five screens across and five screens high.

Our most popular LCD walls are about 16’ wide by 10’ tall. Also, when measuring your ceiling height, keep in mind that most walls don’t go all the way down to the floor. So you’ll need to add that into your total height need.

The image on an LCD wall will be sharper than on LED walls, especially while standing nearby, since it’s made from HD panels. Will have very thin seams between each LCD screen, called bezels.

Since an LCD Wall are basically fancy computer monitors, it’s typically easier to create content. If your content looks great on a standard computer monitor with a 16:9 aspect ratio, it will look good on an LCD wall. Your AV provider will give you dimensions and resolution requirements once you decide on the size you need, and can also help you determine where the seams (or “bezels”) will be so none of your image gets cut off.

Much lower than LCD — but you’ll still need to make sure your venue has enough power capabilities. Your video wall provider can tell you how much power you’ll need.

Imagine an LCD video wall is like a tray of lasagna. Reliable, beautiful, and sturdy — but you can only increase the size of a tray of lasagna so much. Affordable, but it has a limit in size.

At Rise Display, we make LED ticker displays easy. From getting a quote, to installation, to support after the sale, our turnkey ticker solution is seamless and painless. Whether you want a basic ticker display for a finance lab, a scrolling news ticker, or a multi-ticker integrated display that wows passersby, our custom ticker solutions can be built to fit your space and your budget. Our Rise Ticker App iscompletely integrated with our quality hardware and designed to run for years with no complications.And with our 5-year, on-site guarantee, you can rest easy knowing you’ve purchased a high-quality, reliable ticker display that will be easy to set up, program, and maintain.

While most ticker displays are straight and wall-mounted, we also support ceiling mounts, vertical mounts, flexible curved cabinets, wrap corners, and even outdoor weatherproofed units. For curved units, we can flex to a minimum of a two-foot radius.

While the majority of our installs are in North America, we can ship displays anywhere and work remotely with your local installer. The hardware is universal and we have variable power supplies to adapt to different electrical standards. Understanding the data source and compatibility is key to ensuring success.

We have our own Rise Ticker App and licenses with financial and sports providers for the live content. Once a ticker is connected to your network (wired or wireless), your firewall must allow outbound TCP/IP access to cms.risedisplay.com via port 9090 to receive the live updates. No dedicated computer equipment is required. All of the “smarts” are built into the ticker display.More network setup info.

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