10.1 inch 1200x1920 hdmi ips lcd display free sample

Take your experiments and projects to the next level with the Seeed HDMI IPS LCD display. Measuring 10.1 inches from corner to corner, it has a 1,200-by-1,920p resolution and connects via the HDMI interface. A backlight function button allows you to adjust the brightness to suit your environment. The display can also be powered using the built-in micro-USB port. In addition to working with Raspberry Pi, the screen can be used with Windows-based devices.

Here we offer you this high-resolution, ultra-wide viewing angle ISP HDMI display. Specifically, this display has a resolution of 1200*1920 and a viewing angle up to double 178 degrees. It is small and light, easy to carry, and compatible with most platforms with HDMI interface. No need for drivers, true plug and play.

10.1inch Capacitive Touch Screen LCD (B), with Case and Toughened Glass Cover, 1280×800, HDMI, IPS Screen, Supports Raspberry Pi and PC, Low Power Consumption

Kingtech 1280*800 IPS/ free viewing angle 10 inch LCD display module is our leading TFT display product. This high brightness 10 inch TFT display can stand very high temperatures because we invested an NRE fee to the LCD panel"s original manufacturer and have custom-made special crystal to handle the high temperature.

Kingtech, as one of LCD screen suppliers, can offer many kinds of top-quality TFT LCD display products, such as 10.1 inch 1200x1920 HDMI IPS LCD display, 10.1 inch LCD screen with brightness of 1000 nits, and so on.

Kingtech 1280*800 IPS/ free viewing angle 10 inch lcd display screen of high brightness has the below features:The most important feature of this high brightness 10.1 inch lcd display is the wide temperature at -30℃ to +80℃ for both operating and storage temperatures. Normally the LCD 10.1 inch 1280*800 resolution display is only -10℃ to +60℃ or -20℃ to +70℃ operating temperature.

Our high brightness 10.1 lcd display module can stand so high temperature because we invested an NRE fee to the LCD panel"s original manufacturer and have custom-made special crystal to handle the high temperature.

We designed an HDMI board to match with a high brightness LCD display so that you can just connect our display to your computer easily and quickly to check the display effect.

HDMI board available to this 10.1-inch model can be used as an alternative to Mitsubishi model AA101TA12 and Innolux model. If you are looking for these displays, you can try our 10.1 inch LCD display.

A number of people have used a Motorola Atrix Lapdock to add a screen and keyboard with trackpad to RasPi, in essence building a RasPi-based laptop computer. Lapdock is a very clever idea: you plug your Atrix smart phone into Lapdock and it gives you an 11.6" 1366 x 768 HDMI monitor with speakers, a keyboard with trackpad, two USB ports, and a large enough battery for roughly 5 hours of use. The smart phone acts as a motherboard with "good enough" performance. The advantage over a separate laptop or desktop computer is that you have one computing device so you don"t need to transfer files between your phone and your desk/laptop.

Unfortunately for Motorola, Lapdock was not successful (probably because of its US$500 list price) and Motorola discontinued it and sold remaining stock at deep discounts, with many units selling for US$50-100. This makes it a very attractive way to add a modest size HDMI screen to RasPi, with a keyboard/trackpad and rechargeable battery power thrown in for free.

Lapdock has two connectors that plug into an Atrix phone: a Micro HDMI D plug for carrying video and sound, and a Micro USB plug for charging the phone and connecting to the Lapdock"s internal USB hub, which talks to the Lapdock keyboard, trackpad, and two USB ports. With suitable cables and adapters, these two plugs can be connected to RasPi"s full-size HDMI connector and one of RasPi"s full-size USB A ports.

The hardest part about connecting Lapdock is getting the cables and adapters. Most HDMI and USB cables are designed to plug into jacks, whereas the Lapdock has plugs so the cables/adapters must have Micro HDMI and Micro USB female connections. These are unusual cables and adapters, so check the links.

Lapdock uses the HDMI plug to tell if a phone is plugged in by seeing if the HDMI DDC/CEC ground pin is pulled low. If it"s not, Lapdock is powered off. As soon as you plug in a phone or RasPi, all the grounds short together and Lapdock powers itself on. However, it only does this if the HDMI cable actually connects the DDC/CEC ground line. Many cheap HDMI cables do not include the individual ground lines, and rely on a foil shield connected to the outer shells on both ends. Such a cable will not work with an unmodified Lapdock. There is a detailed "blog entry on the subject at element14: Raspberry Pi Lapdock HDMI cable work-around. The "blog describes a side-benefit of this feature: you can add a small power switch to Lapdock so you can leave RasPi attached all the time without draining the battery.

When you do not connect a HDMI monitor, the GPU in the PI will simply rescale (http://en.wikipedia.org/wiki/Image_scaling) anything that would have appeared on the HDMI screen to a resolution suitable for the TV standard chosen, (PAL or NTSC) and outputs it as a composite video signal.

The Broadcom BCM2835 only provides HDMI output and composite output. RGB and other signals needed by RGB, S-VIDEO or VGA connectors are however not provided, and the R-PI also isn"t designed to power an unpowered converter box.

Note that any conversion hardware that converts HDMI/DVI-D signals to VGA (or DVI-A) signals may come with either an external PSU, or expects power can be drawn from the HDMI port. In the latter case the device may initially appear to work, but there will be a problem, as the HDMI specs only provide in a maximum of 50mA (@ 5 Volt) from the HDMI port, but all of these adapters try to draw much more, up-to 500mA, in case of the R-PI there is a limit of 200mA that can be drawn safely, as 200mA is the limit for the BAT54 diode (D1) on the board. Any HDMI to VGA adapter without external PSU might work for a time, but then burn out D1, therefore Do not use HDMI converters powered by the HDMI port!

Alternatively, it may be possible to design an expansion board that plugs into the LCD headers on the R.Pi. Here is something similar for Beagleboard:

The schematics for apples iPhone 3gs and 4g suggest they speak DSI, thus they can probably be connected directly. The older iPhones use a "Mobile Pixel Link" connection from National Semiconductor. The 3GS panel (480×320) goes as low as US $14.88, while the 4G one (960×640, possibly the LG LH350WS1-SD01, with specifications) can be had for US $17.99 or as low as US $14.28. The connectors used might be an issue, but this connector might fit. Additional circuitry might be necessary to provide the display with required 1.8V and 5.7V for operation, and an even higher voltage for the backlight.

Parallel interface displays can be found in many sizes, usually up to 7" and more. Parallel interfaces are usually 8 or 16-bits wide (sometimes 18 or 24-bit wide), plus some control-lines. The Raspberry Pi P1-connector does not contain enough GPIOs for 16-bit wide parallel displays, but this could be solved by borrowing some GPIOs from the CSI-connector or from P5 (on newer Raspberry Pis). Alternatively, some additional electronics (e.g. shift-registers or a CPLD) can be used, which could also improve the framerate or lower the CPU-load.

AdvaBoard RPi1: Raspberry Pi multifunction extension board, incl. an interface and software for 3.2"/5"/7" 16-bit parallel TFT-displays incl. touchscreen with up to 50 frames/s (3.2", 320x240)

Texy"s 2.8" TFT + Touch Shield Board: HY28A-LCDB display with 320 x 240 resolution @ 10 ~ 20fps, 65536 colors, assembled and tested £24 plus postage, mounts on GPIO pins nicely matching Pi board size, or via ribbon cable

Note: Under MENU, there are mufunctions: Color, Adjust, OSD, Function, Sound and Exit. And under MODE SELECT, you can select AV1, AV2 (the jack is set inside so unavailable), VGA, and HDMI.

After removing the 4 standoffs on top, make sure the 4 ones at bottom are tightened, and then place the blue acrylic onside. Pay attention to the direction: place the acrylic with the opening at your right side (the buttons side, see the red arrow below) for the SD card. Also the long slot should be placed at the top of the monitor which is to leave the room for pin tips underneath the board (green arrow). So now put the Raspberry Pi on the acrylic. You"re suggested to plug in the SD card before fixing, or else it will be tricky to do so after installation is done. Accordingly, note that pins at the monitor top and SD card at the buttons side.

After boot up, if the screen shows no signal and turn black, press the bottom MODE SELECT button and select the HDMI mode. The screen will then display the homepage.

If you encounter the difficulties in reading too small characters or incomplete display, that would be wrong resolution. Here let"s see how to solve this resolution issue.

First, you need a USB mouse and a USB keyboard connected to your Raspberry Pi. After your Raspberry Pi is booted up, it should display a GUI as follows:

Seeed studio 10.1" display with a resolution of 1200 x 1920 pixels with wide viewing angle IPS matrix. Works with Raspberry Pi in versions 3B+ 3B+ 2B, 1B+, 1B, 1A and Zero and Zero W via the HDMI and USB cable.

The screen is small, lightweight and easy to carry. Compatible with most platforms with HDMI. In addition, the display has an adjustable backlight, which is controlled using the buttons located at the back.

In order to run the screen, you must connect the device to a Raspberry Pi via the supplied wire: HDMI and microUSB. The screen works with the latest operating system Raspbian without the need to install drivers. However, in order for the screen to display the picture properly, you should change the resolution in the configuration file. To do this, open the file config.txt and then at the end add the following statements.

5" and 7" screens can be supplied with the usual USB interface, while a 10.1" requires the current larger than the maximum supply current USB 2.0 (500 mA).

This 10.1 inch high-resolution 1280x800 IPS display is especially designed as a monitor for Lattepanda(which could be used as windows 10 development board), Raspberry Pi and other mini PC. The HDMI/VGA/AV interfaces ensure its wide compatibility. Making a digital photo frame, playing a video, adding a face for your robot, you can expand your imagination, make more fun.

The mentioned product is a IPS (In-Plane Switching) display with a screen resolution of 1280×800 pixels [1].It has a contrast ratio of 800:1 and a brightness of 350 cd/m^2 [1].

In terms of dimensions, the whole display has 230×149 mm, with an actual screen area of 217×135 mm [1], which means most of the display area is occupied by the actual screen.

In terms of input signal interfaces, the device supports AV, VGA and HDMI (version 1.2) [1], which means we can directly connect the Raspberry Pi to it without the need to any additional converter.

Note however that the LCD needs to be connected to a controller board, which is already included in the whole product package. We will check more on the controller board below.

If you already have some transformer that can output a voltage in this range, you can use it as long as you confirm that its polarity is the same as the one the LCD uses. Additionally, you need to make sure that it can support enough current draw to power the LCD, which can only be determined by testing since the documentation of the device doesn’t state its current draw. Taking into account these factors, my recommendation is to use the power supply wall adapter recommended by the seller, to avoid damaging the LCD.

The display was tested on a Raspberry Pi 3 model B+. Nonetheless, since it has standard video input interfaces, it should be usable with other versions of the Raspberry Pi and even with other boards. One such example are the powerful LattePanda boards, which are also mentioned as supported on the product page of the display.

Additionally, the controller board is connected to another small PCB which contains some keys that are used to control the LCD (the left connection). This PCB is shown below at figure 3.

The power supply is also connected to the LCD controller board, which is responsible to supply the display. We also connect the Raspberry (or the other device used) to this board using one of the 3 available interfaces (HDMI, AV or VGA).

It’s important to mention that the display and the keys PCB board already have cables with interfaces ready to connect to the controller board, which means that no soldering is required and the connections are simple.

What needs special attention are the display connections since they have less connectors than the pins of the controller board. So we need to put them in the correct positions, as indicated in figure 4.

As already mentioned, the controller board is connected to a smaller PCB which contains some keys to control the LCD. These keys basically correspond to the typical interface many monitors have, with a couple of buttons to turn it on, off or control parameters such as brightness.

So basically, for this LCD, we have a button to turn on and off the display. The LED present on that board changes between red and green, depending if the display is off or on, respectively.

Then, we have a menu button that, when clicked, opens an interface like the one shown on figure 6, which allows to adjust some parameters of the display.

Finally, we have a button that allows to change between the supported input interfaces. If, after connecting your device to the display you get a “No signal” message, then most likely you need to click that button to change the input interface to the correct one.

The analyzed display is a nice addition to be used with a Raspberry Pi. It is a compact solution that can even be used with other mini computers similar to the Raspberry Pi. Even though it requires some additional connections other than the HDMI one, it should be easy enough to get started.

This 10.1 inch high-resolution 1200*1920 IPS display is especially designed as a monitor for LattePanda V1 a windows 10 development board (not compatible with LattePanda Alpha & Delta). It gives users the ability to create all-in-one, integrated projects such as tablets, infotainment systems and embedded projects，even adding a face for your robot, you can expand your imagination, make more fun.

Up to 224 PPI, this 1200x1920 display will creating an impression of sharp print-like text. And only one connection to the LattePanda is required, it connects via an FPC cable which handles power and signal conversion. So, there is no need for the adapter board and it releases HDMI port to build dual-screen.

A wide variety of 1920x1200 lcd screen options are available to you, You can also choose from original manufacturer, odm 1920x1200 lcd screen,As well as from tft, ips, and standard.