Search results for "Adafruit Pi"
Adafruit Adafruit BrainCraft HAT - Machine Learning for Raspberry Pi 4
Features: 1.54' IPS TFT display with 240x240 resolution that can show text or video Stereo speaker ports for audio playback - either text-to-speech, alerts or for creating a voice assistant. Stereo headphone out for audio playback through a stereo system, headphones, or powered speakers. Stereo microphone input - perfect for making your very own smart home assistants Two 3-pin JST STEMMA connectors that can be used to connect more buttons, a relay, or even some NeoPixels! STEMMA QT plug-and-play I2C port can be used with any of Adafruits 50+ I2C STEMMA QT boards or can be used to connect to Grove I2C devices with an adapter cable. 5-Way Joystick + Button for user interface and control. Three RGB DotStar LEDs for colorful LED feedback. The STEMMA QT port means you can attach heat image sensors like the Panasonic Grid-EYE or MLX90640. Heat-Sensitive cameras can be used as a person detector, even in the dark! An external accelerometer can be attached for gesture or vibration sensing such as machinery/industrial predictive maintenance projects Please note: A Raspberry Pi 4 is not included.
€ 49,95
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Adafruit Adafruit Zero Spy Camera for Raspberry Pi Zero (160 Degree Focal Angle)
Is your house haunted? Or, rather, are you convinced that your house is haunted but have never been able to prove it since you've never had a camera that integrated with your Raspberry Pi Zero but was still small enough that the ghosts wouldn't notice it? Luckily, the spy camera for Raspberry Pi Zero is smaller than a thumbnail with a high enough resolution to see people, ghosts, or whatever it is you're looking for. It's about the size of a cell phone camera – the module being just 8.6 x 8.6 mm – with only a 2' cable, so you can create an extra compact and sneaky little spy cam. It has a 160-degree focal angle for a very wide/distorted fisheye effect that's great for security systems or watching a big swath of the living room or roadway. Like the Raspberry Pi camera board, it attaches to your Raspberry Pi Zero v1.3 or Zero W by way of the small socket on the board's edge closest to the 'PWR in' port. This interface uses the dedicated CSI interface, which was designed especially for interfacing to cameras. The CSI bus is capable of extremely high data rates, and it exclusively carries pixel data. The camera is connected to the BCM2835 processor on the RPi via the CSI bus, a higher bandwidth link which carries pixel data from the camera back to the processor. This bus travels along the ribbon cable that attaches the camera board to the Pi. The ribbon cables are compatible with both the RPi Zero v1.3 and RPi Zero W. The sensor itself has a native resolution of 5 megapixels and has a fixed focus lens onboard. It has similar specs as the original RPi camera, but is not as high-res as the new RPi camera v2! Specifications Camera Module Dimensions: 8.6 x 8.6 mm Lens Diameter: 10 mm Total Length: 60 mm Lens Focal Angle: 160 degrees Weight: 1.9 g
€ 34,95€ 24,95
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Pimoroni Pimoroni Weather HAT for Raspberry Pi
A meteorologically minded Raspberry Pi HAT designed to make hooking up weather sensors a breeze (or a squall, or a gale). Weather HAT is an all-in-one solution for hooking up climate and environmental sensors to a Raspberry Pi. It has a bright 1.54' LCD screen and four buttons for inputs. The onboard sensors can measure temperature, humidity, pressure and light. The sturdy RJ11 connectors will let you easily attach wind and rain sensors. It will work with any Raspberry Pi with a 40-pin header. You could install it outside in a suitable weatherproof enclosure and connect to it wirelessly – logging the data locally or piping it into Weather Underground, a MQTT broker or a cloud service like Adafruit IO. Alternatively, you could house your weather Pi inside and run wires to your weather sensors outside - making use of the nice screen to display readouts. Features 1.54' IPS LCD screen (240 x 240) Four user-controllable switches BME280 temperature, pressure, humidity sensor (datasheet) LTR-559 light and proximity sensor (datasheet) Nuvoton MS51 microcontroller with inbuilt 12-bit ADC (datasheet) RJ11 connectors for connecting wind and rain sensors (optional) HAT-format board Fully-assembled Compatible with all 40-pin header Raspberry Pi models Downloads Python library Schematic Included Weather HAT 2 x 10 mm standoffs
€ 49,95
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Pimoroni Pimoroni Badger 2040
Badger 2040 is a hackable, programmable badge with E Ink display, powered by Raspberry Pi RP2040.The Badger 2040 is equipped with plenty of buttons so you can easily change what's displayed on the screen, a slot so you can clip it onto a lanyard and a battery connector so you can keep things portable and refresh the screen whilst on the go.Here are some things you could do with it! Switch between images, pronouns or secret identities at the push of a button Make yourself into a mobile weather station or air quality monitor (by adding a sensor breakout) Store important QR codes for getting into places (or to Rickroll people) Make a tiny to-do list and tick stuff off Display inspirational badger quotes or educational badger facts of the day Want to show your Badger the world? We've put together a convenient Badger + Accessory Kit which contains batteries, a lanyard and everything else that's needed to get portabello.Features 2.9' black and white E Ink display (296 x 128 pixels) Ultra wide viewing angles Ultra low power consumption Dot pitch – 0.227 x 0.226 mm Powered by RP2040 (Dual Arm Cortex M0+ running at up to 133 Mhz with 264 kB of SRAM) 2 MB of QSPI flash supporting XiP Five front user buttons Reset and boot buttons (the boot button can also be used as a user button) White LED USB-C connector for power and programming JST-PH connector for attaching a battery (input range 2.7-6 V) High-precision voltage reference for battery level monitoring Qw/ST (Qwiic/STEMMA QT) connector Fully-assembled (no soldering required) Schematic Mechanical drawing C++/MicroPython libraries SoftwareBecause it's a RP2040 board, Badger 2040 is firmware agnostic! You can program it with C/C++, MicroPython or CircuitPython.C++/MicroPython libraries contain some nifty software tweaks to let you get the most out of your Badger. You'll get best performance using C++, but if you're a beginner we'd recommend using our batteries included MicroPython build for ease of getting started. Download Pirate brand MicroPython (special Badger edition) Getting Started with Badger 2040 C++ examples MicroPython examples MicroPython function reference You can also use CircuitPython on your Badger 2040. CircuitPython drivers are designed to work on a bunch of different microcontrollers so you won't get the fancy RP2040-architecture specific tweaks that you'll find in the library, but you will get access to all the nice conveniences of Adafruit's ecosystem. Download CircuitPython for Badger 2040 Getting Started with CircuitPython CircuitPython examples BadgerOS ported to CircuitPython by Stephane BeBoX
€ 24,95
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Elektor March/April 2022
Build Your Own RISC-V ControllerFirst Steps with the NEORV32 RISC-V Softcore for Low-Cost FPGAs How to Use Arduino’s Serial PlotterPlotting Graphs With Arduino Is Easy CLUE from AdafruitA Smart Solution for IoT Projects Buffer Board for the Raspberry Pi 400Protect the I/Os Raspberry Pi RP2040 Boards Aplenty A Handbook on DIY Electronic Security and EspionageSRAM Heated or Deep-Frozen Component IdentificationTips & Tricks, Best Practices and Other Useful Information DIY Touchless Light Switch Starting out in ElectronicsMatching and Transforming What’s New in Embedded Development?Rust and Keeping IoT Deployments Updated Infographics How the Industrial and Automotive Sectors Will Benefit from 5G Moving Coil RelaysPeculiar Parts, the series HomeLab ToursEverything Revolves Around the Tools... Understanding the Neurons in Neural Networks (Part 4)Embedded Neurons Magnetic Levitation the Very Easy WayThe Third and Most Compact Version PLC Programming with the Raspberry Pi and the OpenPLC ProjectVisualization of PLC Programs with AdvancedHMI From Life's ExperiencePack Up and Leave Under Your RadarMicrocontrollers You Should Know About Monitor and Debug Over the AirA Solution for Arduino, ESP32 and Co. Portable Temperature- and Humidity-Measuring DeviceUsing Ready-Made Modules Lithium Battery Pack RepairSave Money + More Power! GUIs with PythonMeme-Generator Three Questions to Build OnWhy, What, and Who? HexadokuThe Original Elektorized Sudoku
€ 10,95
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Elektor Digital Elektor March/April 2022 (PDF)
Build Your Own RISC-V ControllerFirst Steps with the NEORV32 RISC-V Softcore for Low-Cost FPGAs How to Use Arduino’s Serial PlotterPlotting Graphs With Arduino Is Easy CLUE from AdafruitA Smart Solution for IoT Projects Buffer Board for the Raspberry Pi 400Protect the I/Os Raspberry Pi RP2040 Boards Aplenty A Handbook on DIY Electronic Security and EspionageSRAM Heated or Deep-Frozen Component IdentificationTips & Tricks, Best Practices and Other Useful Information DIY Touchless Light Switch Starting out in ElectronicsMatching and Transforming What’s New in Embedded Development?Rust and Keeping IoT Deployments Updated Infographics How the Industrial and Automotive Sectors Will Benefit from 5G Moving Coil RelaysPeculiar Parts, the series HomeLab ToursEverything Revolves Around the Tools... Understanding the Neurons in Neural Networks (Part 4)Embedded Neurons Magnetic Levitation the Very Easy WayThe Third and Most Compact Version PLC Programming with the Raspberry Pi and the OpenPLC ProjectVisualization of PLC Programs with AdvancedHMI From Life's ExperiencePack Up and Leave Under Your RadarMicrocontrollers You Should Know About Monitor and Debug Over the AirA Solution for Arduino, ESP32 and Co. Portable Temperature- and Humidity-Measuring DeviceUsing Ready-Made Modules Lithium Battery Pack RepairSave Money + More Power! GUIs with PythonMeme-Generator Three Questions to Build OnWhy, What, and Who? HexadokuThe Original Elektorized Sudoku
€ 7,50
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Elektor Maart/April 2022 (NL)
Bouw uw eigen RISC-V-controllerEerste stappen met de NEORV32 RISC-V softcore voor goedkope FPGA’s Het gebruik van Arduino’s seriële plotterGrafieken plotten met Arduino is gemakkelijk CLUE van AdafruitEen slimme oplossing voor IoT-projecten Bufferboard voor de Raspberry Pi 400Bescherm uw I/O’s Raspberry Pi RP2040-boards in overvloed Een handboek voor DHZ elektronische beveiliging en spionageSRAM – gebakken of diepgevroren Onderdelen identificerenTips & trucs, vakkunstigheden en andere nuttige informatie DHZ aanraakloze lichtschakelaar Alle begin......gaat compenseren en transformeren Nieuwe embedded-ontwikkelingenRust en het up-to-date houden van IoT-implementaties Infographics Hoe de industrie- en automobielsector zullen profiteren van 5G Relais met bewegende spoelVreemde onderdelen Oost West Lab BestAlles draait om de bank... Kennismaking met neuronen in neurale netwerkenDeel 4: embedded neuronen Magnetische levitatie “the very easy way”De derde en meest compacte versie PLC-programmering met de Raspberry Pi en het OpenPLC-projectVisualisatie van PLC-programma’s met AdvancedHMI Uit het leven gegrepenInpakken en wegwezen Onder de radarMicrocontrollers die u zou moeten kennen Draadloos monitoren en debuggenvoor Arduino, ESP32 en co. Draagbare temperatuur- en vochtigheidsmetermet gebruiksklare modules Lithium-accupacks reparerenSpaart geld + geeft meer kracht! GUI's maken met PythonMeme-Generator De drie grote vraagtekensWaarom wat wie Hexadoku
€ 14,95
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Elektor Digital Elektor Maart/April 2022 PDF (NL)
Bouw uw eigen RISC-V-controllerEerste stappen met de NEORV32 RISC-V softcore voor goedkope FPGA’s Het gebruik van Arduino’s seriële plotterGrafieken plotten met Arduino is gemakkelijk CLUE van AdafruitEen slimme oplossing voor IoT-projecten Bufferboard voor de Raspberry Pi 400Bescherm uw I/O’s Raspberry Pi RP2040-boards in overvloed Een handboek voor DHZ elektronische beveiliging en spionageSRAM – gebakken of diepgevroren Onderdelen identificerenTips & trucs, vakkunstigheden en andere nuttige informatie DHZ aanraakloze lichtschakelaar Alle begin......gaat compenseren en transformeren Nieuwe embedded-ontwikkelingenRust en het up-to-date houden van IoT-implementaties Infographics Hoe de industrie- en automobielsector zullen profiteren van 5G Relais met bewegende spoelVreemde onderdelen Oost West Lab BestAlles draait om de bank... Kennismaking met neuronen in neurale netwerkenDeel 4: embedded neuronen Magnetische levitatie “the very easy way”De derde en meest compacte versie PLC-programmering met de Raspberry Pi en het OpenPLC-projectVisualisatie van PLC-programma’s met AdvancedHMI Uit het leven gegrepenInpakken en wegwezen Onder de radarMicrocontrollers die u zou moeten kennen Draadloos monitoren en debuggenvoor Arduino, ESP32 en co. Draagbare temperatuur- en vochtigheidsmetermet gebruiksklare modules Lithium-accupacks reparerenSpaart geld + geeft meer kracht! GUI's maken met PythonMeme-Generator De drie grote vraagtekensWaarom wat wie Hexadoku
€ 9,95
Members € 8,96
iLabs iLabs Challenger RP2040 NFC
The Challenger RP2040 NFC is a small embedded computer, equipped with an advanced on-board NFC controller (NXP PN7150), in the popular Adafruit Feather form factor. It is based on an RP2040 microcontroller chip from the Raspberry Pi Foundation which is a dual-core Cortex-M0 that can run on a clock up to 133 MHz. NFC The PN7150 is a full featured NFC controller solution with integrated firmware and NCI interface designed for contactless communication at 13.56 MHz. It is fully compatible with NFC forum requirements and is greatly designed based on learnings from previous NXP NFC device generation. It is the ideal solution for rapidly integrating NFC technology in any application, especially small embedded systems reducing Bill of Material (BOM). The integrated design with full NFC forum compliancy gives the user all the following features: Embedded NFC firmware providing all NFC protocols as pre-integrated feature. Direct connection to the main host or microcontroller, by I²C-bus physical and NCI protocol. Ultra-low power consumption in polling loop mode. Highly efficient integrated power management unit (PMU) allowing direct supply from a battery. Specifications Microcontroller RP2040 from Raspberry Pi (133 MHz dual-core Cortex-M0) SPI One SPI channels configured I²C Two I²C channel configured (dedicated I²C for the PN7150) UART One UART channel configured Analog inputs 4 analog input channels NFC module PN7150 from NXP Flash memory 8 MB, 133 MHz SRAM memory 264 KB (divided into 6 banks) USB 2.0 controller Up to 12 MBit/s full speed (integrated USB 1.1 PHY) JST Battery connector 2.0 mm pitch On board LiPo charger 450 mA standard charge current Dimensions 51 x 23 x 3,2 mm Weight 9 g Note: Antenna is not included. Downloads Datasheet Quick start example
€ 22,95€ 17,95
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iLabs iLabs Challenger RP2040 WiFi/BLE MkII with Chip Antenna
The Challenger RP2040 WiFi is a small embedded computer equipped with a WiFi module, in the popular Adafruit Feather form factor. It is based on an RP2040 microcontroller chip from the Raspberry Pi Foundation which is a dual-core Cortex-M0 that can run on a clock up to 133 MHz. The RP2040 is paired with a 8 MB high-speed flash capable of supplying data up to the max speed. The flash memory can be used both to store instructions for the microcontroller as well as data in a file system and having a file system available makes it easy to store data in a structured and easy to program approach. The device can be powered from a Lithium Polymer battery connected through a standard 2.0 mm connector on the side of the board. An internal battery charging circuit allows you to charge your battery safely and quickly. The device is shipped with a programming resistor that sets the charging current to 250 mA. This resistor can be exchanged by the user to either increase or decrease the charging current, depending on the battery that is being used. The WiFi section on this board is based on the Espressif ESP8285 chip which basically is a ESP8266 with 1 MB flash memory integrated onto the chip making it a complete WiFi only requiring very few external components. The ESP8285 is connected to the microcontroller using a UART channel and the operation is controlled using a set of standardized AT-commands. Specifications Microcontroller RP2040 from Raspberry Pi (133 MHz dual-core Cortex-M0) SPI One SPI channel configured I²C One I²C channel configured UART One UART channel configured (second UART is for the WiFi chip) Analog inputs 4 analog input channels WLAN controller ESP8285 from Espressif (160 MHz single-core Tensilica L106) Flash memory 8 MByte, 133 MHz SRAM memory 264 KByte (divided into 6 banks) USB 2.0 controller Up to 12 MBit/s full speed (integrated USB 1.1 PHY) JST Battery connector 2.0 mm pitch Onboard LiPo charger 250 mA standard charge current Onboard NeoPixel LED RGB LED Dimensions 51 x 23 x 3,2 mm Weight 9 g Downloads Datasheet Design files Product errata
€ 17,95
Members € 16,16
iLabs iLabs Challenger RP2040 SD/RTC
The Challenger RP2040 SD/RTC is an Arduino/CircuitPython compatible Adafruit Feather format microcontroller board based on the Raspberry Pi Pico chip. This board is equipped with an microSD card reader and a Real Time Clock making it super useful for data logging applications. MicroSD Card This board is equipped with a microSD card connector that will house standard microSD cards allowing your application to have many gigabytes of storage room for sensor data or what ever you want to place on it. Together with a fancy display you could also store cool images. Real Time Clock (RTC) MCP79410 is a highly integrated real time clock with nonvolatile memory and many other advanced features. These features include a battery switchover circuit for backup power, a timestamp to log power failures and digital trimming for accuracy. Using a low-cost 32.768 kHz crystal or other clock source, time is tracked in either a 12-hour or 24-hour format with an AM/PM indicator and timing to the second, minute, hour, day of the week, day, month and year. As an interrupt or wakeup signal, a multifunction open drain output can be programmed as an Alarm Out or as a Clock Out that supports 4 selectable frequencies. Specifications Microcontroller RP2040 from Raspberry Pi (133 MHz dual-core Cortex-M0) SPI One SPI channel configured I²C One I²C channel configured UART One UART channel configured Analog inputs 4 analog input channels Flash memory 8 MB, 133 MHz SRAM Memory 264 KB (divided into 6 banks) USB 2.0 controller Up to 12 MBit/s full speed (integrated USB 1.1 PHY) JST Battery connector 2.0 mm pitch On board LiPo charger 500 mA standard charge current RTC MCP79410 (uses I²C0 (Wire) for communication) SD Card One SPI channel used (uses SPI1 to connect to the SD socket) Dimensions 51 x 23 x 3,2 mm Weight 9 g Downloads Datasheet RunCPM image including HW I/O port support CPM File image for RunCPM Getting started with RunCPM for the Challenger RP2040 SD/RTC board CircuitPython download page
€ 17,95
Members € 16,16
iLabs iLabs Challenger RP2040 LoRa (EU868)
The Challenger RP2040 LoRa is an Arduino/CircuitPython compatible Adafruit Feather format microcontroller board based on the Raspberry Pi Pico (RP2040) chip.The transceiver features a LoRa long range modem that provides ultra-long range spread spectrum communication and high interference immunity whilst minimizing current consumption.LoRaThe integrated module LoRa module (RFM95W) can achieve a sensitivity of over -148 dBm utilizing a low cost crystal and bill of materials. The high sensitivity combined with the integrated +20 dBm power amplifier yields industry leading link budget making it optimal for any application requiring range or robustness. LoRa also provides significant advantages in both blocking and selectivity over conventional modulation techniques, solving the traditional design compromise between range, interference immunity and energy consumption.The RFM95W is connected to the RP2040 via SPI channel 1 and a few GPIO’s that is required for signaling. A U.FL connector is used to attach your LoRa antenna to the board. 168 dB maximum link budget +20 dBm – 100 mW constant RF output vs. V supply +14 dBm high efficiency PA Programmable bit rate up to 300 kbps High sensitivity: down to -148 dBm Bullet-proof front end: IIP3 = -12.5 dBm Excellent blocking immunity Low RX current of 10.3 mA, 200 nA register retention Fully integrated synthesizer with a resolution of 61 Hz FSK, GFSK, MSK, GMSK, LoRaTM and OOK modulation Built-in bit synchronizer for clock recovery Preamble detection 127 dB Dynamic Range RSSI Automatic RF Sense and CAD with ultra-fast AFC Packet engine up to 256 bytes with CRC Specifications Microcontroller RP2040 from Raspberry Pi (133 MHz dual-core Cortex-M0) SPI Two SPI channels configured (second SPI connected to RFM95W) I²C One I²C channel configured UART One UART channel configured Analog inputs 4 analog input channels Radio module RFM95W from Hope RF Flash memory 8 MB, 133 MHz SRAM memory 264 KB (divided into 6 banks) USB 2.0 controller Up to 12 MBit/s full speed (integrated USB 1.1 PHY) JST Battery connector 2.0 mm pitch On board LiPo charger 450 mA standard charge current Dimensions 51 x 23 x 3,2 mm Weight 9 g Downloads Datasheet Design files
€ 24,95
Members € 22,46