ips tft display cover 3d quotation

AZ Displays offers a range of Digital TFT Panels from 1.77″ to 15.4″ with an emphasis 4.3” , 5 “, and 7.0” displays. The list below is our standard offering. However, AZ Displays has many more customized options and special sizes available. Please contact us for more information.

This 10.1 inch TFT LCD display has a 1024x600 resolution screen with IPS technology, which delivers sunlight readable brightness, better color reproduction, better image consistency, and better optical characteristics at any angle. For extra protection, this 24-bit true color TFT also includes an EMI filter on the input power supply line. This 10.1" display is RoHS compliant with LVDS interface, and does not include a touchscreen. This 10.1" IPS display has been designed with the same mechanical footprint and pinout and includes the same HX8282 driver IC as the TN display, making this a compatible replacement option for the TN models.

Choose from a wide selection of interface options or talk to our experts to select the best one for your project. We can incorporate HDMI, USB, SPI, VGA and more into your display to achieve your design goals.

Equip your display with a custom cut cover glass to improve durability. Choose from a variety of cover glass thicknesses and get optical bonding to protect against moisture and debris.

TFTdisplays moduleare liquid-crystal display panel with thin-film transistor technology, bonding with IC driver, backlight unit, and flex cable, sometimes assemble control board with difference interface.TFT displayis active display with high contrast than monochrome lcd, TheTFT display technology could offers full RGB display in wide range display colors and tunes, high display resolution. We could get rich colors, detailed images, clear and bright graphics display from a tft lcd module.

PCB HERO provide wide range tft lcd display module from small sizes to medium sizes. Our small tft lcd sizes( diagonal size of tft active area) have 0.9” tft lcd, 1.8” tft lcd, 2.2” tft lcd, 2.4”tft lcd, 2.8” tft lcd display module, 3.2” tft lcd, 3.5” tft lcd module, 4.3” tft display module, 5” tft lcd, 5.6” tft display, 5.7 inch tft, 7” tft lcd, medium sizes tft module such as 8” tft lcd, 9” tft, 10.1” tft lcd display module, 12.1” tft lcd, and so on. Our wide range standard tft lcd module could meet the most of application for industrial, medical, automotive application. Such as industrial control system, coffee machine, medical equipment, POS system, GPS navigator, white goods, kitchen display, cooking machine, energy control display, IOT, and etc.

PCB HERO tft lcd moduleincluding standard tft-lcd modules, wide viewing angle IPS tft lcd, sunlight readable tft lcd display with high brightness tft and transflective tft lcd, reflective tft, Wide temperature tft lcd, bar type tft lcd, and smart tft lcd module with serial interface for industrial display application. Resistive touch panel and projected capacitive touch screen (PCAP) with tft lcd, in landscape or portrait type. Beside color tft display, we have monochrome tft lcd with high transmissive ratio and power saving for special application such as 3D printer mask screen.

Our tft lcd module have variety interface including MCU, RGB,TTL, LVDS, MIPI DSI, serial SPI, I2C interface. The tft lcd display resolution from such as 80x160 pixels, QVGA 240X320, HVGA 320X480, VGA 640X480 tft lcd display module, and high resolution such 1024X600, 1024X768, 1280X800, FHD 1920X1080 resolution.

Nio Color 3MP is a 3-megapixel high-bright color display system with LED backlights, providing excellent image quality for confident diagnoses. Its exceptional brightness (calibrated at 500 cd/m2) helps you discern even the tiniest detail - even after many years of use.

The new Nio Color 3MP offers the best image quality in the market for a 3MP color solution. Its high brightness and high contrast ratio enable you to unveil even the subtlest details. With the integrated smart features, you can easily take control and improve your productivity. SpotViewTM, for example, allows you to focus on an area of interest to unveil even more details. And with DimViewTM, any auxiliary displays can be automatically dimmed. The Nio Color 3MP is also an excellent solution for radiologists who want to angle their desktop: it lets you choose your preferred viewing angle and offers highly ergonomic display configuration.

Using Barco’s integrated front sensor, the Nio Color 3MP works perfectly with Barco’s QAWeb Enterprise solution for automated Quality Assurance and calibration. QAWeb Enterprise guarantees stable DICOM images throughout the display’s lifetime. By default, Barco displays are equipped with a protective cover to safeguard your investment. Thanks to the high-performance LED backlights, the Nio Color 3MP requires less power, even at higher calibrated luminance. This has a positive impact on both maintenance and operational costs.

Barco is the only company that provides complete system solutions, from display and controllers to workflow tools and calibration via QAWeb Enterprise. All components are covered by our full 5-year warranty. At product release, Barco extensively tests the displays compatibility with all major PACS applications.

In 3D mode, through the supplied ergonomic kit, composed by a light-weight frame and a replaceable 3D eye-shield, multiple users at the same time will be able to see the same FHD content, with excellent depth perception even from different viewing angles and distances.

Available as either DP/HDMI (MDFC-8232 3HB) or DP/SDI (MDFC-8232 3SB), this monitor is compatible with the most common 3D and 2D video formats typical of modern microscopes and laparoscopic camera systems.

The highly durable and scratch-resistant full-glass front surface, and the snap-in lockable connector cover, result in a clutter-free and easy-to-clean design ideal for application in sterile environments. The front glass also minimizes reflection for better visibility. The designed in standard VESA-100 mounting plate allows easy mounting on surgical booms and spring arms.

The lower the response time the better. Be aware of ISO response time figures and grey to grey (G2G) transition figures as you will need to understand the difference. Screens with a G2G quoted response time use ‘Response Time Compensation’ (RTC) technologies, sometimes referred to as overdrive. These technologies are used to boost pixel response times and in practice can make quite a lot of difference. This is particularly important with non-TN Film panels (i.e. IPS, PVA, MVA etc)

The wider the viewing angles the better. Be wary of how they calculate their figures. Sometimes they will try sneaking things like listed them when CR > 5 instead of when CR > 10 to inflate their numbers. Again real life performance might not match quoted specs. You will normally see TN Film panels listed with a 170/160 viewing angle (a classic indication that the screen is using TN Film technology by the way). IPS-type and VA-type panels will normally feature a 178/178 viewing angle spec, but in reality the performance does vary.

A. very important thing to consider is what panel technology the screen uses you are interested in buying. While specs may look similar on paper, performance may vary quite considerably between the models due to the underlying panel technology used. The most common technologies used in the desktop monitor market are TN Film, IPS-type (and similar variants like PLS and AHVA) and VA -type. These are all produced by a range of panel manufacturers and offer a variety of strengths and weaknesses. There is a reasonable amount of talk about panel technologies with many people quick to jump on a bandwagon and claim one is superior to another. To be honest, they all still have their place in the modern market, and due to their different characteristics, can play a key part in finding the right monitor for your use.

PLS (Plane to Line Switching)= S-PLS, a Samsung technology exclusive to them and very similar to LG.Display’s IPS in performance and can therefore be called an “IPS-type” technology

AHVA (Advanced Hyper-Viewing Angle) = developed by AU Optronics as another alternative to LG.Display’s IPS, very similar again and so can be called “IPS-type”

Colour gamut – don’t assume that a higher colour gamut is better! The gamut represents the colour space that the backlighting unit of the monitor allows the screen to display. You need to understand that most normal content is based on a certain colour space (sRGB) and that there can be issues if you view this using a wide gamut screen. See here for more information.

A. Generally nowadays with all the ultra-low response time models available, ghosting caused by slow pixel response times is just not an issue for the majority of users. Performance has improved significantly over the years and blurring and ghosting has been largely eliminated on the faster displays. The use of RTC technologies (overdrive) significantly helps improve response times and speed up pixel transitions. This is particularly important on IPS/VA type displays which can be very slow where RTC is not used. Look out for response time specs quoted with a “G2G” (grey to grey) response time as that should indicate the use of overdrive technologies.

Nowadays screens supporting high refresh rates (120Hz+) input frequencies are becoming more and come common, and these can help reduce motion blur and ghosting and improve gaming performance considerably. They are also able to support higher frame rates than traditional 60Hz displays and some are also capable of supporting 3D stereoscopic content through active shutter glasses. Do be careful of assuming that a screen advertised as supporting 3D is in fact able to support 120Hz though, as some 3D models do not support this and instead use passive methods to produce the 3D effect (see here for more info on 3D technologies). Refresh rate of the panel does have a direct impact on motion clarity and for optimal gaming performance you will want to consider those high refresh rate displays above 60Hz.

Ghosting and motion blur perception may also depend on how susceptible you are as a user, as one person may see no ghosting, another may see lots on the same panel. The best bet is to try and see a TFT in action in a shop and see for yourself, if that’s not possible you will have to settle for the opinions of other users and take the plunge! Also be careful to get an idea of real life performance in practice, and don’t just rely on quoted specs. While they are often a good rough guide to the gaming performance, they are not always reliable.

One area which cannot be eliminated fully through response time improvements is perceived motion blur. This is related to how the human eye tracks movement on hold-type displays like LCD’s. In recent years several methods have been used to help provide improved motion blur for users. Models featuring LightBoost backlights for 3D gaming were found to be “hackable” to bring about motion blur benefits through the use of their strobed backlight system. Other displays have now introduced native strobed backlights to offer similar benefits. Look out for models with Motion Blur Reduction backlights like the BenQ XL2420Z / XL2720Z (Blur Reduction mode), Eizo Foris FG2421 (Turbo 240) and Asus ROG Swift PG278Q (ULMB) for instance. ULMB as a feature is common on NVIDIA G-sync enabled displays where high refresh rate is used.

Have a read here about response times if you are unsure about what specs mean or want more information. Generally modern TN Film panels will offer the fastest response times, and often also support 120Hz input frequencies for 3D support / extended frame rates. Look out for models with a quoted “G2G” response time indicating they also use overdrive which can really help in practice. Modern IPS-type panels can also be very fast where overdrive is applied well, so again look for “G2G” figures. High refresh rate IPS panels are also becoming more common which helps improve motion clarity further. Other technologies like PVA and MVA are unfortunately quite slow in practice by modern standards, even where overdrive or high refresh rates are used. Check reviews to be sure of an individual screens performance wherever possible.

A. As a rule of thumb, it would normally be best to use the digital video connection end to end to connect your device to your monitor. For a PC, this would commonly be DisplayPort, HDMI or DVI which offer a pure digital end to end connection between the graphics card and the monitor. DisplayPort is needed to run the high resolution/high refresh rate panels so you will need to ensure your graphics card has a DP output. Some screens or cards use Mini DP instead of the full size version, but that is simply a different size connection and can be easily inter-changed with “normal” DisplayPort. Cables which are DP at one end, and Mini DP at the other are common and simple to use.

HDMI and DisplayPort are also common digital connections now being offer, but unlike DVI are also capable of carrying audio as well as video. The picture quality should not be any different between DVI, HDMI and DisplayPort in theory as long as no additional video “enhancements” are applied when using one over the other. Bandwidth requirements will vary so this might influence which type you need to use depending on the screen resolution and refresh rate.

Converting between DVI and HDMI is easy and cables are readily available to offer that if needed (keeping in mind you will lose the sound transmission when it reaches the DVI). Converting between DVI/HDMI and DisplayPort is far more tricky and not simple to achieve. It is very hit and miss and working active adapters are expensive. We would advise avoiding the attempt to convert DP to HDMI/DVI if you can.

A. There is a lot of talk about colour depth on TFT screens, now more than ever with the emergence of 6-bit IPS and VA panels. At one time TN Film was the main 6-bit technology but today that is no longer the case. It’s important to put this into perspective though, and not jump on the bandwagon of 8-bit being much, much better than 6-bit. Or even 10-bit being much better than 8-bit.

An 8-bit display would offer a colour palette of 16.7 million colours. They offer a ‘true’ colour palette, and are generally the choice of manufacturers for colour critical displays over 6-bit panels. On the other hand modern 6-bit screens use a range of Frame Rate Control (FRC) technologies to extend the colour palette from 262,144 colours to around 16.7m. In fact on many modern panels these FRC are very good and in practice you’d be hard pressed to spot any real difference between a 6-bit + FRC display and a true 8-bit display. Colour range is good, screens show no obvious gradation of colours, and they show no FRC artefacts or glitches in normal everyday use. Most average users would never notice the difference and so it is more important to think about the panel technology and your individual uses than get bogged down worrying about 6-bit vs. 8-bit arguments.

Manufacturers use 6-bit panels (+FRC) to help keep costs lower. As a result, a modern range of IPS and VA panels is also now produced which use 6-bit colour depth (+FRC) instead of true 8-bit colour depths. At the other end of the scale there are also some panels which can offer support of 10-bit colour depth. Again these come in two flavours, being either a true 10-bit panel (quite rare and expensive) offering 1.07 billion colours or an 8-bit panel with an additional FRC stage added (1.07 billion colours produced through FRC). The 8-bit +FRC panels are of course more common and will often be used to offer “10-bit” support in desktop displays. With 10-bit colour though there is also an additional consideration which is whether you would ever even be able to use this in your work. You can also only make use of this 10-bit support if you have a full end-to-end 10-bit workflow, including a supporting software, graphics card and operating system which is still very rare and expensive for most users. So for many people the use of a 10-bit capable panel is rather meaningless.

The colour space / gamut capability of a monitor is not determined by the panel technology, but rather by the backlight technology being used. Traditional screens used standard CCFL backlighting which (for simplicity of comparison here) offered a colour space covering the sRGB space almost exactly, which equates to about 72% of the now popular NTSC reference space. With backlighting technology changes and improvements, some screens then started to use WCG-CCFL (Wide Colour Gamut CCFL) backlighting which can offer an extended gamut covering commonly 92% – 102% of the NTSC reference space. Other backlighting technologies like W-LED (White LED) are also becoming very common, and at the moment cover the sRGB space (~68 – 72% NTSC). Some other LED backlights using RGB LED can cover >100% of the NTSC space as well but are prohibitively expensive and rarely used.

While a larger colour space might sound like a good idea, it’s not always for everyone. You need to keep in mind what content you will be viewing on the screen, and what colour space that content is based on. Since sRGB is very common and the standard for many things like Windows and the internet, viewing sRGB content on an extended gamut screen can cause oversaturation of colours and an unrealistic ‘stretching’ of the colours. Reds and greens in particular can appear quite ‘neon’ and some users do not like this. The smaller colour space of the content is, as a very crude description, ‘stretched’ over the larger colour space of the monitor. On the other hand, some applications are colour space aware (e.g. Adobe Photoshop) and so if you are working with extended gamut content, you will prefer an extended gamut screen. I’d certainly recommend reading more into this as it is only a brief summary here. Where a screen has an extended gamut, they sometimes provide an sRGB emulation mode which work to varying degrees. Handy if you might need to use it, but make sure the screen offers a decent performance when in this mode and that it works. At the end of the day, the choice of monitor might very well depend on the colour space you want to work with. For most average users a standard CCFL or W-LED backlit display with a standard sRGB gamut would probably be preferred.

A. The simplest and cheapest way to clean a TFT screen is with a slightly damp cloth; wipe off the left behind water with a towel or similar then smooth/dry completely with a yellow polishing cloth. Be careful not to use products such as toilet paper and kitchen roll as they contain lint and can leave scratches on your beloved screen! Cleaning solution from opticians and lint free clothes for lens cleaning are also very good.

A. Unfortunately dead pixels can be an issue on TFT screens as they are often developed during the manufacturing stage. For retail costs to be kept low the companies cannot afford to make all screens defect-free and check for dead pixels all the time. Pixels can be described in the following ways:

If you want to ensure that you receive a pixel perfect screen (and who wouldn’t at the kind of prices you are paying for the TFT!?!) then you can often pay for pixel checks from some online retailers. Beware though! Never buy a TFT from retailers who offer the pixel check without having the check done as you can be sure the screens they find to be non-perfect will be winging their way to the customers who don’t have the check! The only other option to ensure you get a pixel perfect screen is to check out the panel in a shop in person, then you can see for yourself…..

If you find you have a dead pixel there is not a lot you can do unfortunately. If you have a certain number of dead pixels (usually at least 3 or a certain number centrally on the panel) then the manufacturer will replace the TFT for you, but the number of dead pixels needed before this happens varies between each manufacturer, so check with them before you order if you’re concerned.

If you still have a dead pixel problem, can’t bring it back to life and can’t RMA it under warranty then you can sometimes return it to the stockist if you purchased it online. If you bought online you can take advantage of the “Distance Selling Act” which entitles you to return any item within 7 days as you were not present at the time of purchase. If you are not happy with your TFT you can return it at your cost of postage and often claim a refund or exchange. However, be aware that a lot of places will try and charge you restocking fees and they will almost certainly specify the goods must be packaged and in the same condition as when you received it, so be careful to package it back up nicely. Legally, if the stocker accepts the TFT back as a return governed by the Distance Selling Act, then they are NOT allowed to charge you a restocking fee as covered in the Government Regulations. This selling act is not widely advertised by retailers, but does exist if you really need to use it. You should only have to pay for postage to send it back to them.