raspberry pi 3 model b lcd touch screen setup pricelist

The UCTRONICS 3.5 Inch touch screen is the same size as the standard Raspberry Pi model B/B+, and well-mates with the Raspberry Pi boards. With a tiny size, vivid image, and responsive touchscreen, it is definitely ideal for portable devices and multimedia projects. It is a great replacement for a heavy and bulky HDMI monitor, keyboard, and mouse

Step1: Align the pin 1 of the edge connector between the LCD display and Raspberry pi board, connect the pin 1,2,3,4 then pin 19,20,21,22,23,24,25,26.

Attention: If you want to use the touch function, you need to download and install the driver manually refers to the instructions we provided. The driver includes the settings of the Raspbian OS resolution and touch screen support.

Attention: If you use this display without a Pi, the touch function is not available because the touch function of this display just supports the Raspbian system. Meanwhile, an extra HDMI cable also is required for the video transmission.

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This 3.5" Touch Screen Hat fits right on top of the Raspberry Pi and uses the GPIO pins for both display and touch input. Just place the 3.5" Touch Screen Shield on top of your Raspberry Pi, load the Pi"s SD card with the custom image found at the link at the bottom and you"ll boot directly into the desktop! Use your finger to move the mouse pointer on the screen! The custom image makes this the easiest touch screen setup! If you still prefer to install your own drivers on your existing Raspbian image, follow the directions on the driver install tutorial link at the bottom.

11 TP_IRQ Touch Panel interrupt, low level while the Touch Panel detects touch

Today I received all the parts I need to begin setting up my own personal home dashboard. When I first began my career in programming, Home Automation was always something I’ve been very intrigued with; only it was very expensive and there weren’t many products out there to support it. Now, with the recent boom in IOT devices and products, its easier and far more cost effective to do this on your own.

Apart from just tinkering and learning, It’s something to help my family and I organize our lives, control devices in our home and it’s just plain cool! Earlier this year, I purchased a SmartThings Hub and it’s been a lot of fun controlling my thermostat and door locks. I also have an Amazon Echo which is an amazing device as well! I have a lot of plans with this project, which I will document in future posts. So stay tuned! For now, lets start by setting up the hardware.

HDMI cable. I connected my PI (after the OS install) to a 27in monitor I had laying around. You’ll need this temporarily. You can connect to a laptop or any other device that accepts HDMI. I used it just to make sure the OS installed properly before I connected the touchscreen to the Raspberry Pi.

I decided to use the Raspbian Jessie with Pixel distribution for my setup. (There are many 3rd party images you could choose from also). For this example, we are using Jessie so you can download it here from the Raspberry Pi website by selecting “Download ZIP”. When the image file completes downloading, we are going to install the Raspberry Pi operating system image on an SD card. The image contained in the ZIP archive is over 4GB in size, which means that the archive may use features which are not supported by older unzip tools, on some operating systems. If you find that the download appears to be corrupt or the file is not unzipping correctly, please try using 7Zip (Windows) or The Unarchiver (Macintosh). Both are free of charge! In this setup, I am using a Mac. After the download completes, unzip the file you downloaded. Alright, here we go:

Open “Disk Utility”. To do this, click on the magnifying glass in the top-right corner of your computer screen. Type “disk utility” in the search box that opens, then click on the “Disk Utility” Application that comes up and click on “APPLE SD Card Reader Media”.

Note the “Device:”; it will look something like disk(n) where (n) is a number (for example, disk1). Make sure you take a note of this number. Mine was disk1.

The image file will be copied to the SD Card. You won’t get any feedback while it copies, and it can take several minutes. Leave terminal open and let it do its thing. When the copy is finished enter

to eject the disk (again remembering to replace (n) with the number that you noted before). Remove the SD Card and insert it into your Raspberry Pi 3.

Ok so that wasn’t so bad. Now connect the Raspberry Pi to a monitor, plug in a USB keyboard and mouse and connect the power cord to the Raspberry Pi to boot it up. Here’s how mine looks connected to my monitor. That was quite exciting!

Before we install the screen, let’s make sure we have the latest and greatest. The last 2 commands update the UI. Open up terminal and run the following commands on your Raspberry Pi:

Unpack the touchscreen from the static bag and place it on top of the static bag so that the screen is face down. (don’t remove the protection on the screen)

Take the white ribbon cable (supplied) and connect it to the connector on the board, with the blue mark on one end facing up towards the back of the screen like shown below. I had a tough time getting it in there so take your time. You don’t want to damage it.

The 7” Touchscreen Monitor for Raspberry Pi gives users the ability to create all-in-one, integrated projects such as tablets, infotainment systems and embedded projects.

The 800 x 480 display connects via an adapter board which handles power and signal conversion. Only two connections to the Pi are required; power from the Pi’s GPIO port and a ribbon cable that connects to the DSI port present on all Raspberry Pi’s. Touchscreen drivers with support for 10-finger touch and an on-screen keyboard will be integrated into the latest Raspberry Pi OS for full functionality without a physical keyboard or mouse.

Make your own ‘Internet of Things’ (IoT) devices including a visual display. Simply connect your Raspberry Pi, develop a Python script to interact with the display, and you’re ready to create your own home automation devices with touch screen capability.

A range of educational software and programs available on the Raspberry Pi will be touch enabled, making learning and programming easier on the Raspberry Pi.

Update:As of October 2015 the touchscreen is now supported on the Model B and A Raspberry Pi in Raspbian. You"ll just need to add jumpers from SDA1 and SCL1 on the Pi to SDA and SCL on the display board and to add "ignore_lcd=0" to /boot/config.txt to be up and running!

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Raspberry Pi (single-board computers (SBCs) developed in the United Kingdom by the Raspberry Pi Foundation in association with Broadcom.computer science in schools and in developing countries.target market for uses such as robotics. It is widely used in many areas, such as for weather monitoring,HDMI and USB standards.

After the release of the second board type, the Raspberry Pi Foundation set up a new entity, named Raspberry Pi Trading, and installed Eben Upton as CEO, with the responsibility of developing technology.Sony factory in Pencoed, Wales,

There are three series of Raspberry Pi, and several generations of each have been released. Raspberry Pi SBCs feature a Broadcom system on a chip (SoC) with an integrated ARM-compatible central processing unit (CPU) and on-chip graphics processing unit (GPU), while Raspberry Pi Pico has a RP2040 system on chip with an integrated ARM-compatible central processing unit (CPU).

In 2014, the Foundation released a board with an improved design, Raspberry Pi Model B+. These first-generation boards feature ARM11 processors, are approximately credit-card sized, and represent the standard mainline form factor. Improved A+ and B models were released within a year. A "Compute Module" was released in April 2014 for embedded applications.

The Raspberry Pi 2 was released in February 2015 and initially featured a 900 MHz 32-bit quad-core ARM Cortex-A7 processor with 1 GB RAM. Revision 1.2 featured a 900 MHz 64-bit quad-core ARM Cortex-A53 processor (the same as that in the Raspberry Pi 3 Model B, but underclocked to 900 MHz).

The Raspberry Pi 3 Model B was released in February 2016 with a 1.2 GHz 64-bit quad core ARM Cortex-A53 processor, on-board 802.11n Wi-Fi, Bluetooth and USB boot capabilities.

On Pi Day 2018, the Raspberry Pi 3 Model B+ was launched with a faster 1.4 GHz processor, a three-times faster Gigabit Ethernet (throughput limited to ca. 300 Mbit/s by the internal USB 2.0 connection), and 2.4 / 5 GHz dual-band 802.11ac Wi-Fi (100 Mbit/s).Power over Ethernet (PoE) (with the add-on PoE HAT), USB boot and network boot (an SD card is no longer required).

The Raspberry Pi 4 Model B was released in June 2019ARM Cortex-A72 processor, on-board 802.11ac Wi-Fi, Bluetooth 5, full gigabit Ethernet (throughput not limited), two USB 2.0 ports, two USB 3.0 ports, 1–8 GB of RAM, and dual-monitor support via a pair of micro HDMI (HDMI Type D) ports for up to 4K resolution. The version with 1 GB RAM has been abandoned and the prices of the 2 GB version have been reduced. The 8 GB version has a revised circuit board. The Pi 4 is also powered via a USB-C port, enabling additional power to be provided to downstream peripherals, when used with an appropriate PSU. But the Pi can only be operated with 5 volts and not 9 or 12 volts like other mini computers of this class. The initial Raspberry Pi 4 board has a design flaw where third-party e-marked USB cables, such as those used on Apple MacBooks, incorrectly identify it and refuse to provide power.Tom"s Hardware tested 14 different cables and found that 11 of them turned on and powered the Pi without issue.C0. The manufacturer is now using this chip for the Pi 4 B and Pi 400. However, the tack frequency of the Pi 4 B was not increased in the factory.

The Raspberry Pi 400 was released in November 2020. A modern example of a keyboard computer, it features 4 GB of LPDDR4 RAM on a custom board derived from the existing Raspberry Pi 4 combined with a keyboard in a single case. The case was derived from that of the Raspberry Pi Keyboard.

A Raspberry Pi Zero with smaller size and reduced input/output (I/O) and general-purpose input/output (GPIO) capabilities was released in November 2015 for US$5.

On 28 October 2021, the Raspberry Pi Zero 2 W was launched, a version of the Zero W with a system in a package (SiP) designed by Raspberry Pi and based on the Raspberry Pi 3.

Raspberry Pi Pico was released in January 2021 with a retail price of $4.microcontroller chip; the RP2040, which was designed by Raspberry Pi in the UK.flash memory. It is programmable in C, C++, Assembly, MicroPython, CircuitPython and Rust. The Raspberry Pi Foundation has partnered with Adafruit, Pimoroni, Arduino and SparkFun to build accessories for Raspberry Pi Pico and variety of other boards using RP2040 Silicon Platform.physical computing, similar in concept to an Arduino.

On 30 June 2022, the Raspberry Pi Pico W was launched, a version of the Pico with 802.11n Wi-Fi capability, for US$6. The CYW43439 wireless chip in the Pico W also supports Bluetooth, but the capability was not enabled at launch.

As of 4 May 2021, the Foundation is committed to manufacture most Pi models until at least January 2026. Even the 1 GB Pi 4B can still be specially-ordered.

The Raspberry Pi hardware has evolved through several versions that feature variations in the type of the central processing unit, amount of memory capacity, networking support, and peripheral-device support.

This block diagram describes models B, B+, A and A+. The Pi Zero models are similar, but lack the Ethernet and USB hub components. The Ethernet adapter is internally connected to an additional USB port. In Model A, A+, and the Pi Zero, the USB port is connected directly to the system on a chip (SoC). On the Pi 1 Model B+ and later models the USB/Ethernet chip contains a five-port USB hub, of which four ports are available, while the Pi 1 Model B only provides two. On the Pi Zero, the USB port is also connected directly to the SoC, but it uses a micro USB (OTG) port. Unlike all other Pi models, the 40 pin GPIO connector is omitted on the Pi Zero, with solderable through-holes only in the pin locations. The Pi Zero WH remedies this.

Processor speed ranges from 700 MHz to 1.4 GHz for the Pi 3 Model B+ or 1.5 GHz for the Pi 4; on-board memory ranges from 256 MB to 8 GB random-access memory (RAM), with only the Raspberry Pi 4 having more than 1 GB. Secure Digital (SD) cards in MicroSDHC form factor (SDHC on early models) are used to store the operating system and program memory, however some models also come with onboard eMMC storageSSD storage for its operating system.USB ports. For video output, HDMI and composite video are supported, with a standard 3.5 mm tip-ring-sleeve jack carrying mono audio together with composite video. Lower-level output is provided by a number of GPIO pins, which support common protocols like I²C. The B-models have an 8P8C Ethernet port and the Pi 3, Pi 4 and Pi Zero W have on-board Wi-Fi 802.11n and Bluetooth.

The Broadcom BCM2835 SoC used in the first generation Raspberry PiMHz 32-bit ARM1176JZF-S processor, VideoCore IV graphics processing unit (GPU),cache of 16 KB and a level 2 (L2) cache of 128 KB. The level 2 cache is used primarily by the GPU. The SoC is stacked underneath the RAM chip, so only its edge is visible. The ARM1176JZ(F)-S is the same CPU used in the original iPhone,clock rate, and mated with a much faster GPU.

The earlier V1.1 model of the Raspberry Pi 2 used a Broadcom BCM2836 SoC with a 900 MHz 32-bit, quad-core ARM Cortex-A7 processor, with 256 KB shared L2 cache.64-bit quad-core ARM Cortex-A53 processor,underclocked (by default) to the same 900 MHz CPU clock speed as the V1.1. The BCM2836 SoC is no longer in production as of late 2016.

The Raspberry Pi 3 Model B uses a Broadcom BCM2837 SoC with a 1.2 GHz 64-bit quad-core ARM Cortex-A53 processor, with 512 KB shared L2 cache. The Model A+ and B+ are 1.4 GHz

The Raspberry Pi 4 uses a Broadcom BCM2711 SoC with a 1.5 GHz (later models: 1.8 GHz) 64-bit quad-core ARM Cortex-A72 processor, with 1 MB shared L2 cache.interrupt controller poorly suited for virtualisation, the interrupt controller on this SoC is compatible with the ARM Generic Interrupt Controller (GIC) architecture 2.0, providing hardware support for interrupt distribution when using ARM virtualisation capabilities.

The Raspberry Pi Zero and Zero W use the same Broadcom BCM2835 SoC as the first generation Raspberry Pi, although now running at 1 GHz CPU clock speed.

The Raspberry Pi Zero W 2 uses the RP3A0-AU CPU, a 1 GHz 64 bit ARM Cortex A53, on 512MB of SDRAM. Documentation states this "system-on-package" is a Broadcom BCM2710A1 package, using a BCM2837 Broadcom chip as core, which is an ARM v8 quad-core. The Raspberry Pi 3 also uses the BCM2837, but clocked at 1.2 GHz.

While operating at 700 MHz by default, the first generation Raspberry Pi provided a real-world performance roughly equivalent to 0.041 GFLOPS.Pentium II of 1997–99. The GPU provides 1 Gpixel/s or 1.5 Gtexel/s of graphics processing or 24 GFLOPS of general purpose computing performance. The graphical capabilities of the Raspberry Pi are roughly equivalent to the performance of the Xbox of 2001.

Raspberry Pi 2 V1.1 included a quad-core Cortex-A7 CPU running at 900 MHz and 1 GB RAM. It was described as 4–6 times more powerful than its predecessor. The GPU was identical to the original.

Most Raspberry Pi systems-on-chip could be overclocked to 800 MHz, and some to 1000 MHz. There are reports the Raspberry Pi 2 can be similarly overclocked, in extreme cases, even to 1500 MHz (discarding all safety features and over-voltage limitations). In Raspberry Pi OS the overclocking options on boot can be made by a software command running "sudo raspi-config" without voiding the warranty.temperature reaches 85 °C (185 °F), but it is possible to override automatic over-voltage and overclocking settings (voiding the warranty); an appropriately sized heat sink is needed to protect the chip from serious overheating.

Newer versions of the firmware contain the option to choose between five overclock ("turbo") presets that, when used, attempt to maximise the performance of the SoC without impairing the lifetime of the board. This is done by monitoring the core temperature of the chip and the CPU load, and dynamically adjusting clock speeds and the core voltage. When the demand is low on the CPU or it is running too hot, the performance is throttled, but if the CPU has much to do and the chip"s temperature is acceptable, performance is temporarily increased with clock speeds of up to 1 GHz, depending on the board version and on which of the turbo settings is used.

In the highest (turbo) mode the SDRAM clock speed was originally 500 MHz, but this was later changed to 600 MHz because of occasional SD card corruption. Simultaneously, in high mode the core clock speed was lowered from 450 to 250 MHz, and in medium mode from 333 to 250 MHz.

The CPU of the first and second generation Raspberry Pi board did not require cooling with a heat sink or fan, even when overclocked, but the Raspberry Pi 3 may generate more heat when overclocked.

The early designs of the Raspberry Pi Model A and B boards included only 256 MB of random access memory (RAM). Of this, the early beta Model B boards allocated 128 MB to the GPU by default, leaving only 128 MB for the CPU.framebuffer, and was likely to fail for any video or 3D. 128 MB was for heavy 3D processing, possibly also with video decoding.Nokia 701 uses 128 MB for the Broadcom VideoCore IV.

The later Model B with 512 MB RAM, was released on 15 October 2012 and was initially released with new standard memory split files (arm256_start.elf, arm384_start.elf, arm496_start.elf) with 256 MB, 384 MB, and 496 MB CPU RAM, and with 256 MB, 128 MB, and 16 MB video RAM, respectively. But about one week later, the foundation released a new version of start.elf that could read a new entry in config.txt (gpu_mem=xx) and could dynamically assign an amount of RAM (from 16 to 256 MB in 8 MB steps) to the GPU, obsoleting the older method of splitting memory, and a single start.elf worked the same for 256 MB and 512 MB Raspberry Pis.

The Model A, A+ and Pi Zero have no Ethernet circuitry and are commonly connected to a network using an external user-supplied USB Ethernet or Wi-Fi adapter. On the Model B and B+ the Ethernet port is provided by a built-in USB Ethernet adapter using the SMSC LAN9514 chip.802.11n (150 Mbit/s) and Bluetooth 4.1 (24 Mbit/s) based on the Broadcom BCM43438 FullMAC chip with no official support for monitor mode (though it was implemented through unofficial firmware patchingIEEE 802.11b/g/n/ac WiFi, Bluetooth 4.2, and Gigabit Ethernet (limited to approximately 300 Mbit/s by the USB 2.0 bus between it and the SoC). The Raspberry Pi 4 has full gigabit Ethernet (throughput is not limited as it is not funnelled via the USB chip.)

Raspberry Pi models with a newer chipset can boot from USB mass storage, such as from a flash drive. Booting from USB mass storage is not available in the original Raspberry Pi models, the Raspberry Pi Zero, the Raspberry Pi Pico, the Raspberry Pi 2 A models, and the Raspberry Pi 2 B models with versions lower than 1.2.

Although often pre-configured to operate as a headless computer, the Raspberry Pi may also optionally be operated with any generic USB computer keyboard and mouse.

The video controller can generate standard modern TV resolutions, such as HD and Full HD, and higher or lower monitor resolutions as well as older NTSC or PAL standard CRT TV resolutions. As shipped (i.e., without custom overclocking) it can support the following resolutions: 640×350 EGA; 640×480 VGA; 800×600 SVGA; 1024×768 XGA; 1280×720 720p HDTV; 1280×768 WXGA variant; 1280×800 WXGA variant; 1280×1024 SXGA; 1366×768 WXGA variant; 1400×1050 SXGA+; 1600×1200 UXGA; 1680×1050 WXGA+; 1920×1080 1080p HDTV; 1920×1200 WUXGA.

Although the Raspberry Pi 3 does not have H.265 decoding hardware, the CPU is more powerful than its predecessors, potentially fast enough to allow the decoding of H.265-encoded videos in software.

The Raspberry Pis can also generate 576i and 480i composite video signals, as used on old-style (CRT) TV screens and less-expensive monitors through standard connectors – either RCA or 3.5 mm phono connector depending on model. The television signal standards supported are PAL-B/G/H/I/D, PAL-M, PAL-N, NTSC and NTSC-J.

When booting, the time defaults to being set over the network using the Network Time Protocol (NTP). The source of time information can be another computer on the local network that does have a real-time clock, or to a NTP server on the internet. If no network connection is available, the time may be set manually or configured to assume that no time passed during the shutdown. In the latter case, the time is monotonic (files saved later in time always have later timestamps) but may be considerably earlier than the actual time. For systems that require a built-in real-time clock, a number of small, low-cost add-on boards with real-time clocks are available.

The RP2040 microcontroller has a built-in real-time clock but this can not be set automatically without some form of user entry or network facility being added.

Raspberry Pi 1 Models A+ and B+, Pi 2 Model B, Pi 3 Models A+, B and B+, Pi 4, and Pi Zero, Zero W, Zero WH and Zero W 2 have the same 40-pin pinout called J8 header.

Models A and B provide GPIO access to the ACT status LED using GPIO 16. Models A+ and B+ provide GPIO access to the ACT status LED using GPIO 47, and the power status LED using GPIO 35.

BCM2837: 3D part of GPU at 300 MHz, video part of GPU at 400 MHz,OpenGL ES 2.0 (BCM2835, BCM2836: 24 GFLOPS / BCM2837: 28.8 GFLOPS). MPEG-2 and VC-1 (with licence),1080p30 H.264/MPEG-4 AVC high-profile decoder and encoder

Various operating systems for the Raspberry Pi can be installed on a MicroSD or SD card, depending on the board and available adapters; seen here is the MicroSD slot located on the bottom of a Raspberry Pi 2 board.

The Raspberry Pi Foundation provides Raspberry Pi OS (formerly called Raspbian), a Debian-based Linux distribution for download, as well as third-party Ubuntu, Windows 10 IoT Core, RISC OS, LibreELEC (specialised media centre distribution)Kodi media centre and classroom management.Python and Scratch as the main programming languages, with support for many other languages.firmware is closed source, while unofficial open source is available.seL4 is also supported.

Broadcom VCOS – Proprietary operating system which includes an abstraction layer designed to integrate with existing kernels, such as ThreadX (which is used on the VideoCore4 processor), providing drivers and middleware for application development. In the case of the Raspberry Pi, this includes an application to start the ARM processor(s) and provide the publicly documented API over a mailbox interface, serving as its firmware. An incomplete source of a Linux port of VCOS is available as part of the reference graphics driver published by Broadcom.

Ultibo Core – OS-less unikerel Run Time Library based on Free Pascal. Lazarus IDE (Windows with 3rd party ports to Linux and MacOS). Most Pi models supported.

Alpine Linux – a Linux distribution based on musl and BusyBox, "designed for power users who appreciate security, simplicity and resource efficiency".

Slackware ARM – version 13.37 and later runs on the Raspberry Pi without modification.graphical user interface, Slackware"s default user environment is the textual shell / command line interface.Fluxbox window manager running under the X Window System requires an additional 48 MB of RAM.

Raspberry Pi can use a VideoCore IV GPU via a binary blob, which is loaded into the GPU at boot time from the SD-card, and additional software, that initially was closed source.OpenMax, OpenGL ES or OpenVG), which in turn call an open source driver inside the Linux kernel, which then calls the closed source VideoCore IV GPU driver code. The API of the kernel driver is specific for these closed libraries. Video applications use OpenMAX, OpenGL ES and OpenVG, which both in turn use EGL. OpenMAX and EGL use the open source kernel driver in turn.

The Raspberry Pi Foundation first announced it was working on a Vulkan driver in February 2020.Quake 3 at 100 frames per second on a 3B+ was revealed by a graphics engineer who had been working on it as a hobby project on 20 June.

The official firmware is a freely redistributablebinary blob, that is proprietary software.Linux kernel, with patches to remove the dependency on the mailbox interface being responsive. It is known to work on Raspberry Pi 1, 2 and 3, as well as some variants of Raspberry Pi Zero.

C/C++ Interpreter Ch – Released 3 January 2017, C/C++ interpreter Ch and Embedded Ch are released free for non-commercial use for Raspberry Pi, ChIDE is also included for the beginners to learn C/C++.

Greenfoot – Greenfoot teaches object orientation with Java. Create "actors" which live in "worlds" to build games, simulations, and other graphical programs.

Julia – an interactive and cross-platform programming language/environment, that runs on the Pi 1 and later.Visual Studio Code, are available. See also Pi-specific GitHub repository JuliaBerry.

LiveCode – an educational RAD IDE descended from HyperCard using English-like language to write event-handlers for WYSIWYG widgets runnable on desktop, mobile and Raspberry Pi platforms.

Processing – an IDE built for the electronic arts, new media art, and visual design communities with the purpose of teaching the fundamentals of computer programming in a visual context.

Scratch – a cross-platform teaching IDE using visual blocks that stack like Lego, originally developed by MIT"s Life Long Kindergarten group. The Pi version is very heavily optimised

TensorFlow – an artificial intelligence framework developed by Google. The Raspberry Pi Foundation worked with Google to simplify the installation process through pre-built binaries.

V-Play Game Engine – a cross-platform development framework that supports mobile game and app development with the V-Play Game Engine, V-Play apps, and V-Play plugins.

Gertboard – A Raspberry Pi Foundation sanctioned device, designed for educational purposes, that expands the Raspberry Pi"s GPIO pins to allow interface with and control of LEDs, switches, analogue signals, sensors and other devices. It also includes an optional Arduino compatible controller to interface with the Pi.

Camera – On 14 May 2013, the foundation and the distributors RS Components & Premier Farnell/Element 14 launched the Raspberry Pi camera board alongside a firmware update to accommodate it.flexible flat cable that plugs into the CSI connector which is located between the Ethernet and HDMI ports. In Raspbian, the user must enable the use of the camera board by running Raspi-config and selecting the camera option. The camera module costs €20 in Europe (9 September 2013).OmniVision OV5647 image sensor and can produce 1080p, 720p and 640x480p video. The dimensions are 25 mm × 20 mm × 9 mm.

Infrared Camera – In October 2013, the foundation announced that they would begin producing a camera module without an infrared filter, called the Pi NoIR.

Official Display – On 8 September 2015, The foundation and the distributors RS Components & Premier Farnell/Element 14 launched the Raspberry Pi Touch Display

HAT (Hardware Attached on Top) expansion boards – Together with the Model B+, inspired by the Arduino shield boards, the interface for HAT boards was devised by the Raspberry Pi Foundation. Each HAT board carries a small EEPROM (typically a CAT24C32WI-GT3)

In February 2015, a switched-mode power supply chip, designated U16, of the Raspberry Pi 2 Model B version 1.1 (the initially released version) was found to be vulnerable to flashes of light,xenon camera flashes and greenlaser pointers. The U16 chip has WL-CSP packaging, which exposes the bare silicon die. The Raspberry Pi Foundation blog recommended covering U16 with opaque material (such as Sugru or Blu-Tak) or putting the Raspberry Pi 2 in a case.

Technology writer Glyn Moody described the project in May 2011 as a "potential ITPRO.Ian Livingstone suggested that the BBC could be involved in building support for the device, possibly branding it as the BBC Nano.The Centre for Computing History strongly supports the Raspberry Pi project, feeling that it could "usher in a new era".ARM"s CEO Warren East at an event in Cambridge outlining Google"s ideas to improve UK science and technology education.

Harry Fairhead, however, suggests that more emphasis should be put on improving the educational software available on existing hardware, using tools such as Google App Inventor to return programming to schools, rather than adding new hardware choices.

In October 2012, the Raspberry Pi won T3"s Innovation of the Year award,Mark Pesce cited a (borrowed) Raspberry Pi as the inspiration for his ambient device project MooresCloud.British Computer Society reacted to the announcement of enhanced specifications by stating, "it"s definitely something we"ll want to sink our teeth into."

The Raspberry Pi community was described by Jamie Ayre of FOSS software company AdaCore as one of the most exciting parts of the project.fanzine around the platform called Raspberry Jam events have been held across the UK and around the world.

As of January 2012state and private sectors, with around five times as much interest from the latter. It is hoped that businesses will sponsor purchases for less advantaged schools.Premier Farnell said that the government of a country in the Middle East has expressed interest in providing a board to every schoolgirl, to enhance her employment prospects.

In 2014, the Raspberry Pi Foundation hired a number of its community members including ex-teachers and software developers to launch a set of free learning resources for its website.

In 2018, NASA launched the JPL Open Source Rover Project, which is a scaled down version of Curiosity rover and uses a Raspberry Pi as the control module, to encourage students and hobbyists to get involved in mechanical, software, electronics, and robotics engineering.

There are a number of developers and applications that are using the Raspberry Pi for home automation. These programmers are making an effort to modify the Raspberry Pi into a cost-affordable solution in energy monitoring and power consumption. Because of the relatively low cost of the Raspberry Pi, this has become a popular and economical alternative to the more expensive commercial solutions.

In June 2014, Polish industrial automation manufacturer TECHBASE released ModBerry, an industrial computer based on the Raspberry Pi Compute Module. The device has a number of interfaces, most notably RS-485/232 serial ports, digital and analogue inputs/outputs, CAN and economical 1-Wire buses, all of which are widely used in the automation industry. The design allows the use of the Compute Module in harsh industrial environments, leading to the conclusion that the Raspberry Pi is no longer limited to home and science projects, but can be widely used as an Industrial IoT solution and achieve goals of Industry 4.0.

In March 2018, SUSE announced commercial support for SUSE Linux Enterprise on the Raspberry Pi 3 Model B to support a number of undisclosed customers implementing industrial monitoring with the Raspberry Pi.

In January 2021, TECHBASE announced a Raspberry Pi Compute Module 4 cluster for AI accelerator, routing and file server use. The device contains one or more standard Raspberry Pi Compute Module 4s in an industrial DIN rail housing, with some versions containing one or more Coral Edge tensor processing units.

The Organelle is a portable synthesizer, a sampler, a sequencer, and an effects processor designed and assembled by Critter & Guitari. It incorporates a Raspberry Pi computer module running Linux.

OTTO is a digital camera created by Next Thing Co. It incorporates a Raspberry Pi Compute Module. It was successfully crowd-funded in a May 2014 Kickstarter campaign.

Slice is a digital media player which also uses a Compute Module as its heart. It was crowd-funded in an August 2014 Kickstarter campaign. The software running on Slice is based on Kodi.

AutoPi TMU device is a telematics unit which is built on top of a Raspberry Pi Compute Module 4 and incorporates the philosophy of which Raspberry Pi was built upon.

During the COVID-19 pandemic, demand increased primarily due to the increase in remote work, but also because of the use of many Raspberry Pi Zeros in ventilators for COVID-19 patients in countries such as Colombia,

A project was launched in December 2014 at an event held by the UK Space Agency. The Astro Pi was an augmented Raspberry Pi that included a sensor hat with a visible light or infrared camera. The Astro Pi competition, called Principia, was officially opened in January and was opened to all primary and secondary school aged children who were residents of the United Kingdom. During his mission, British ESA astronaut Tim Peake deployed the computers on board the International Space Station.

In 2017, the European Space Agency ran another competition open to all students in the European Union called Proxima. The winning programs were run on the ISS by Thomas Pesquet, a French astronaut.

According to Upton, the name "Raspberry Pi" was chosen with "Raspberry" as an ode to a tradition of naming early computer companies after fruit, and "Pi" as a reference to the Python programming language.

In 2006, early concepts of the Raspberry Pi were based on the Atmel ATmega644 microcontroller. Its schematics and PCB layout are publicly available.trustee Eben Upton assembled a group of teachers, academics and computer enthusiasts to devise a computer to inspire children.

The Foundation"s goal was to offer two versions, priced at US$25 and $35. They started accepting orders for the higher priced Model B on 29 February 2012,

August 2011 – 50 alpha boards are manufactured. These boards were functionally identical to the planned Model B,LXDE desktop on Debian, 1080p,Full HD MPEG-4 video over HDMI.

Early 2012 – During the first week of the year, the first 10 boards were put up for auction on eBay.The Centre for Computing History in Cambridge, England.

19 February 2012 – The first proof of concept SD card image that could be loaded onto an SD card to produce a preliminary operating system is released. The image was based on Debian 6.0 (Squeeze), with the LXDE desktop and the Midori browser, plus various programming tools. The image also runs on QEMU allowing the Raspberry Pi to be emulated on various other platforms.

29 February 2012 – Initial sales commence 29 February 2012web-shops of the two licensed manufacturers selling Raspberry Pi"s within the United Kingdom, Premier Farnell and RS Components, had their websites stalled by heavy web traffic immediately after the launch (RS Components briefly going down completely).

March 2012 – The Debian port is initiated by Mike Thompson, former CTO of Atomz. The effort was largely carried out by Thompson and Peter Green, a volunteer Debian developer, with some support from the Foundation, who tested the resulting binaries that the two produced during the early stages (neither Thompson nor Green had physical access to the hardware, as boards were not widely accessible at the time due to demand).proof of concept image distributed by the Foundation before launch was also Debian-based, it differed from Thompson and Green"s Raspbian effort in a couple of ways. The POC image was based on then-stable Debian Squeeze, while Raspbian aimed to track then-upcoming Debian Wheezy packages.embedded-application binary interface (EABI).armhf architecture in Wheezy intended to make Debian run on the ARM VFP hardware floating-point unit, while armel was limited to emulating floating point operations in software.build cluster.

24 August 2012 – Hardware accelerated video (H.264) encoding becomes available after it became known that the existing licence also covered encoding. Formerly it was thought that encoding would be added with the release of the announced camera module.MPEG-2 and Microsoft"s VC-1. Also it was announced that the Pi will implement CEC, enabling it to be controlled with the television"s remote control.

6 September 2012 – Announcement that in future the bulk of Raspberry Pi units would be manufactured in the UK, at Sony"s manufacturing facility in Pencoed, Wales. The Foundation estimated that the plant would produce 30,000 units per month, and would create about 30 new jobs.

24 October 2012 – The Foundation announces that "all of the VideoCore driver code which runs on the ARM" had been released as free software under a BSD-style licence, making it "the first ARM-based multimedia SoC with fully-functional, vendor-provided (as opposed to partial, reverse engineered) fully open-source drivers", although this claim has not been universally accepted.

October 2012 – It was reported that some customers of one of the two main distributors had been waiting more than six months for their orders. This was reported to be due to difficulties in sourcing the CPU and conservative sales forecasting by this distributor.

17 December 2012 – The Foundation, in collaboration with IndieCity and Velocix, opens the Pi Store, as a "one-stop shop for all your Raspberry Pi (software) needs". Using an application included in Raspbian, users can browse through several categories and download what they want. Software can also be uploaded for moderation and release.

3 June 2013 – "New Out of Box Software" or NOOBS is introduced. This makes the Raspberry Pi easier to use by simplifying the installation of an operating system. Instead of using specific software to prepare an SD card, a file is unzipped and the contents copied over to a FAT formatted (4 GB or bigger) SD card. That card can then be booted on the Raspberry Pi and a choice of six operating systems is presented for installation on the card. The system also contains a recovery partition that allows for the quick restoration of the installed OS, tools to modify the config.txt and an online help button and web browser which directs to the Raspberry Pi Forums.

28 February 2014 – On the day of the second anniversary of the Raspberry Pi, Broadcom, together with the Raspberry Pi foundation, announced the release of full documentation for the VideoCore IV graphics core,

7 April 2014 – The official Raspberry Pi blog announced the Raspberry Pi Compute Module, a device in a 200-pin DDR2 SO-DIMM-configured memory module (though not in any way compatible with such RAM), intended for consumer electronics designers to use as the core of their own products.

14 July 2014 – The official Raspberry Pi blog announced the Raspberry Pi Model B+, "the final evolution of the original Raspberry Pi. For the same price as the original Raspberry Pi model B, but incorporating numerous small improvements people have been asking for".

2 February 2015 – The official Raspberry Pi blog announced the Raspberry Pi 2. Looking like a Model B+, it has a 900 MHz quad-core ARMv7 Cortex-A7 CPU, twice the memory (for a total of 1 GB) and complete compatibility with the original generation of Raspberry Pis.

14 May 2015 – The price of Model B+ was decreased from US$35 to $25, purportedly as a "side effect of the production optimizations" from the Pi 2 development.CHIP, a lower-priced competitor discontinued in April 2017.

26 November 2015 – The Raspberry Pi Foundation launched the Raspberry Pi Zero, the smallest and cheapest member of the Raspberry Pi family yet, at 65 mm × 30 mm, and US$5. The Zero is similar to the Model A+ without camera and LCD connectors, while smaller and uses less power. It was given away with the Raspberry Pi magazine Magpi No. 40 that was distributed in the UK and US that day – the MagPi was sold out at almost every retailer internationally due to the freebie.

29 February 2016 – Raspberry Pi 3 with a BCM2837 1.2 GHz 64-bit quad processor based on the ARMv8 Cortex-A53, with built-in Wi-Fi BCM43438 802.11n 2.4 GHz and Bluetooth 4.1 Low Energy (BLE). Starting with a 32-bit Raspbian version, with a 64-bit version later to come if "there is value in moving to 64-bit mode". In the same announcement it was said that a new BCM2837 based Compute Module was expected to be introduced a few months later.

February 2016 – The Raspberry Pi Foundation announces that they had sold eight million devices (for all models combined), making it the best-selling UK personal computer, ahead of the Amstrad PCW.

25 April 2016 – Raspberry Pi Camera v2.1 announced with 8 Mpixels, in normal and NoIR (can receive IR) versions. The camera uses the Sony IMX219 chip with a resolution of 3280 × 2464. To make use of the new resolution the software has to be updated.

10 October 2016 – NEC Display Solutions announces that select models of commercial displays to be released in early 2017 will incorporate a Raspberry Pi 3 Compute Module.

14 October 2016 – Raspberry Pi Foundation announces their co-operation with NEC Display Solutions. They expect that the Raspberry Pi 3 Compute Module will be available to the general public by the end of 2016.

14 March 2018 – On Pi Day, Raspberry Pi Foundation introduced Raspberry Pi 3 Model B+ with improvements in the Raspberry PI 3B computers performance, updated version of the Broadcom application processor, better wireless Wi-Fi and Bluetooth performance and addition of the 5 GHz band.

2 November 2020 – Raspberry Pi 400 launched. It is a keyboard which incorporates Raspberry Pi 4 into it. GPIO pins of the Raspberry Pi 4 are accessible.

21 January 2021 – Raspberry Pi Pico launched. It is the first microcontroller-class product from Raspberry Pi. It is based on RP2040 Microcontroller developed by Raspberry Pi.

Hattersley, Lucy. "Raspberry Pi 4, 3A+, Zero W – specs, benchmarks & thermal tests". The MagPi magazine. Raspberry Pi Trading Ltd. Retrieved 28 May 2020.

"Ten millionth Raspberry Pi, and a new kit – Raspberry Pi". 8 September 2016. Retrieved 9 September 2016. we"ve beaten our wildest dreams by three orders of magnitude

"Tested: 10+ Raspberry Pi 4 USB-C Cables That Work". Tom"s Hardware. 13 July 2019. Retrieved 21 July 2019. you"ll still need an AC adapter that delivers 5 volts and at least 3 amps of power so, unless you already have one, your best bet might be to buy the official Raspberry Pi 4 power supply, which comes with a built-in cable and goes for $8 to $10.

Upton, Eben (28 October 2021). "New product: Raspberry Pi Zero 2 W on sale now at $15". Raspberry Pi Trading. Retrieved 2 December 2021. Raspberry Pi Zero 2 W uses the same Broadcom BCM2710A1 SoC die as the launch version of Raspberry Pi 3

Halfacree, Gareth (March 2020). "Raspberry Pi 4 now comes with 2GB RAM Minimum". The MagPi. No. 91. Raspberry Pi Press. p. 6. Retrieved 28 May 2020. we say farewell to the 1GB model

Upton, Eben (20 October 2021). "1GB Raspberry Pi 4 makes a comeback". Raspberry Pi Trading. Retrieved 16 November 2021. we are reintroducing the 1GB variant at the $35 price point

Brose, Moses (30 January 2012). "Broadcom BCM2835 SoC has the most powerful mobile GPU in the world?". Grand MAX. Archived from the original on 18 February 2012. Retrieved 13 April 2012.

Merten, Dr. Maik (14 September 2019). "Raspi-Kernschau – Das Prozessor-Innenleben des Raspberry Pi 4 im Detail" [Raspi-kernel-show – The inner life of the Raspberry Pi 4 processor in detail]. C"t (in German). 2019 (20): 164–169.

"Introducing turbo mode: up to 50% more performance for free". Raspberrypi.org. 19 September 2012. Archived from the original on 12 April 2015. Retrieved 20 September 2012.

"Pi Screen limited to 1920 by RISC OS:-". RISC OS Open. Retrieved 6 January 2016. 2048 × 1152 monitor is the highest resolution the Pi"s GPU can handle [presumably with non-low frame-rate ..] The monitors screen info confirms the GPU is outputting 2048×1152

Adams, James (3 April 2014). "Raspberry Pi Compute Module electrical schematic diagram" (PDF). Raspberry Pi Foundation. Archived from the original (PDF) on 30 May 2014. Retrieved 22 September 2014.

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Adams, James (7 April 2014). "Comment by James Adams on Compute Module announcement". Raspberry Pi Foundation. Archived from the original on 21 September 2014. Retrieved 22 September 2014.

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"New video features! MPEG-2 and VC-1 decode, H.264 encode, CEC". Raspberry Pi Foundation. Archived from the original on 25 August 2012. Retrieved 26 August 2012.

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Rockman, Simon (21 February 2012). "Is Raspberry Pi a mid-life crisis?". ZDNet. Retrieved 24 February 2012. Just because young teens led the way in computing in the 1980s doesn"t mean it should, will or can happen again. Those outside the tech age bubble have better things to do.

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"Raspberry Pi • View topic – Raspberry Pi as the successor of BBC Micro". raspberrypi.org. 22 April 2012. Retrieved 12 June 2013. The Foundation trustees tried very hard to get an agreement to use the BBC Micro name, right up to May 2011. /../ Eben touched on the subject a bit during his speech at the Beeb@30 celebration at the beginning of the month

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"New 8-megapixel camera board on sale at $25". 25 April 2016. Retrieved 6 May 2016. both visible-light and infrared cameras based on the Sony IMX219 8-megapixel sensor, at the same low price of $25. They"re available today from our partners RS Components and element14

The Mag Pi Magazine issue 53, Page 10, Raspberry Pi Foundation, On 25 November, it was confirmed that total sales of the Raspberry Pi have now topped 11 million.

Raspberry Pi gets $45M to meet demand for low-cost PCs and IoT, TechCrunch / Natasha Lomas@riptari(twitter), 21 September 2021, While, in total, the Pi Foundation also said it"s shipping over 42 million (Pi-powered) PCs to more than 100 countries.

Impact Stories: Raspberry Pi, The Index Projewct / Ditte Fiil Ravn, With 43 million computers sold worldwide and 95% of its products exported outside the UK, the globe has grown fond of pocket-sized computers.

One decade, 46 million units: Happy birthday, Raspberry Pi, The Register / Richard Speed, Upton tells us that approximately 46 million units have been manufactured to date.

Raspberry Pi boards have revolutionized the electronics hobby world with their simple credit card-sized DIY computer kits. Today, almost anyone with a basic electronics assembly and coding knowledge could set up a Raspberry Pi system of their own.

In order to create a small computer of your own, all you need to have is a raspberry pi board, a display unit and a keyboard (optional). If you are able to find the perfect touch screen, you can create a great DIY computer of your own.

Today, we are going to list down all of the best Raspberry Pi compatible LCD screens available online. These screens are ranked and rated based on the following factors.

Rule of thumb, larger the better. The best of the LCD screens for a Raspberry Pi we got here have a 1080P high resolution and is a full touch screen. There are higher variants available as well but we believe that this is a standard benchmark.

The next important thing that you need to look for in a screen is its compatibility with the various systems that you may be using it other than the Raspberry Pi.

This refers to the ports and other connectivity options through which you can set up the screen to the board. It includes the standard HDMI pots to USB ports and even WiFi compatibility as well. Higher the number of I/O ports, the better

First on our list is an LCD touch screen straight from the official house of Raspberry Pi. It is a 7 inches large touch display that is specifically created for the Raspberry Pi board.

Though compatible with all the existing Raspberry Pi models, the hole line up for installation is good enough only for Raspberry A+, Raspberry B+, Raspberry Pi2

Next on our list is a screen by Kuman, one of the top manufacturer’s in the realm of hobby electronics. This one too is a 7 inches large TFT capacitative touch screen.

Yet another Kuman 7 inches HD Display Screen, this one is quite different from the previous Kuman display screen. That difference is not just in the screen resolution but in a wide range of other things as well.

Next on our list is 1 large 10.1 inches LED Display. The Elecrow HDMI supported LED display monitor supports all the old and new Raspberry Pi models like the Pi 4, 3, 2, and B, B+ models as well.

Apart from Raspberry Pi models, it is also compatible with PS3, PS4, WiiU and XBOX360 and can also be used for video, for car headrest and as a small display for medical equipment too

In this entry, SunFounder comes with a 10.1 inches large HDMI supported IPS LCD display monitor. It has a high resolution of 1280 X 800 pixels and also comes with a camera holder stand.

Next on our list is another SunFounder Raspberry Pi Compatible screen. This one is a simple 7 inches large LCD Display screen with built-in speakers too.

Next product on our list is from a brand called ELECROW. Their LCD screen comes with 5-inches size display and high-resolution picture. It is a resistive touchscreen monitor and comes with a touch pen for easy use.

This LCD touch screen is from SunFounder which has similar dimensions and aesthetical aspect as the previous 10.1 inches Screen by SunFounder and are essentially the same. This is just an older model of the same product.

The last but not least product from our list is a 7-inch LDC touch screen for Raspberry Pi. It supports mini PC like Raspberry 1B+ / 2B / 3B / 3A+/ 3B+/ 4B.

This is quite problematic as you need to select the one from the plenty of choices available in the industry. Some of them are costly-cheap and some offer low-high performances.

But it’s up to you to take the correct decisions as per your requirement. To make it happen, you must acquire some knowledge in technology stuff which becomes very easy for you to pick the right one.

Given below are some of the factors that most of the people ask for while purchasing the Raspberry Pi display kits. Get to know about them in detail to make a good choice.

The very first one in the buying guide list is the Price. The price of the displays tends to be more expensive because it comes with the number of features like resolution, size and many more.

So when you make a purchase, check whether the device is within your budget or not. If it so, then you can happily add the item to cart and wish for it.

But the problem arises when you are unable to afford the money or willing to use the item to fulfill your basic needs. For them, we provided the raspberry pi display kits that come with amazing features at very low prices. Read the product information to know which product best suits your requirements.

Brightness refers to the quality or state of reflecting a light. In other words, brightness can be expressed as the perception elicited by laminating a visual target. It can also be expressed by considering power over a specific area on the monitor. Most of the displays have 200cd/sq.m which is sufficient for a normal usage.

Contrast Ratiodefines the ratio of luminance of the brightest to the darkest color. Generally, the displays are capable of producing high contrast ratio as per the desired. You should also know that there are no specific standards to measure the contrast ratio.

Display resolution or the modes is the number of distinct pixels in each dimension that can be displayed. It is controlled by many of the factors like CRT, flat-panel displays, and LCDs. If the resolution you opt is not compatible then the monitors will stretch and shrink to fit in the specified. It turns result in a great loss of the signal and quality.

Like regular displays, the raspberry pi displays make effective communication between the peripheral devices. For this, it makes use of the connectors. The most common connectors are HDMI, VGA & AV-input. Each of them is illustrated below.

A VGA is a 3-row connector that is provided on many of the display devices like computers, TVs, laptops, and projectors. It is a good quality cable that supports the signal within the bandwidth range of (2-MHz-500MHz).

In this section, we are going to show you exactly how you can connect your Raspberry Pi to an external display screen. First, let us look at how to connect it using an HDMI port

Using the HDMI port to connect a Raspberry Pi to the LCD screen is one of the simplest and easiest ways to go. Here, all you need to do is to take an HDMI cable and plug it on both sides of the devices. One end goes into the HDMI port of the LCD screen and the other one will go right into the Raspberry Pi’s HDMI port. This set up does not require any special drivers software nor does it require any format of post plugin set up.

Raspberry Pi comes with a tiny 15 pin ribbon cable connector that can support a Display Serial Interface or a DSI standard. This enables fast communication between an LCD screen and the chip.

You can use the Raspberry Pi 7 inch touchscreen display by connecting it with the Raspberry Pi board. All you need to do is to first attach the raspberry pi to the back of the display screen using standoffs and screws that come with the kit.

Now connect the Pi board to the ribbon cable and the display control board. Note the ribbon cable pin orientation is proper or not. After this, carefully release the tabs on both sides of the socket so that the cable slides all way. Now secure this by pressing down on the tabs till you hear a click of a lock. Make sure you are not forcing the cable to lock.

If not, you can simply connect a power supply to the control board and then connect a small micro USB cable in the control board’s USB port and the micro USB port of the Pi. This should power on the device. You are now done setting up the device and the screen and once the power flows, the device boots up.

If the screen does not automatically turn on when the power source is connected, you may have to connect an existing HDMI display for updating your Raspberry Pi board and then reboot the device.

The Raspberry Pi 7″ Touch Screen Display from the house of Raspberry has a great colour output of 800 x 400 pixels and its capacitive touch is multi-fingered up to 10 fingers. That and the fact that it is specifically built for Raspberry pi Boards by the Raspberry company makes it the best Raspberry Pi LCD screen for your DIY Raspberry pi kit.

While those were our picks, we are intrigued by your choices, thoughts and opinions. Did we miss out on anything? Or do you want us to add anything else to this list? If so or if you have any questions for us or about the products mentioned, feel free to write to us in the comments section below. Our product expert team will write back to you as soon as possible.

Raspbian OS (Linux) and the latest version of Windows 10 IOT is built to support touch input. We have tested this display with Raspbian OS only, not Windows.

7 inch Capacitive Touch Screen for Raspberry Pi (1024x600) module has an operating temperature in the range -20 ~ +70 degrees centigrade and storage temperature between -30 and +80 degrees centigrade

Is this not the cutest, little display for the Raspberry Pi? It features a 3.5" display with 480x320 16-bit color pixels and a resistive touch overlay so is slightly larger than the Rapsberry Pi board, which is perfect to cover it. The plate uses the high speed SPI interface on the Pi and can use the mini display as a console, X window port, displaying images or video etc. Best of all it plugs right in on top!

I"m using it to run a lighting and irrigation system for my house. The color graphical interface allows me to use BMP images of my house and yard for control screens, and its built into an enclosure set into the wall for a slick professional look. I even put an access from the backside of the wall for wiring it without having to remove the Pi or the touchscreen.

Great responsiveness, inexpensive, can"t beat 10-finger multi touch! The python demos are really neat, too. Only gripe is that the screen isn"t oleophobic, but for the price I"ll take it!

This was easy to install and it looks good. The Touchscreen is responsive and clear, but you might want to use a stylus. The only issue i had is finding a case for it. You"ll want to get one right away, unless you have a 3D printer to make one yourself. The screen is really thin, so I didn"t want to carry it around without some protection. Overall, it"s a great touchscreen, especially for the price, and I like that it is Raspi-branded.

I purchased 5 touchscreen. Two before and three in January. Touch and display quality is superb. After two-three month of use (no rough use; handled with care), display LCD and front touchpanel (black bezel) break apart. They both are connected using a thin double sided tape. I was planning to use in industrial environment but after such issue, I dropped my plan to use it in industrial environment.

Five of two displays are not in good condition. First display"s touch-panel and display LCD was break apart after two-three month. The second among five displays had another issue. Display LCD was mounted slightly right side of the touchpanel. Once you power-up display, it is easily be seen