Specifications
RP2040 microcontroller chip designed by Raspberry Pi in the UK
Dual-core ARM Cortex M0+ processor, with a flexible clock running up to 133 MHz
264 kB SRAM, and 2 MB on-board Flash memory
Castellated module allows soldering directly to carrier boards
USB 1.1 host and device support
Energy-efficient sleep and dormant modes
Drag and drop programming using mass storage via USB
26x multifunction GPIO pins
2x SPI, 2x I²C, 2x UART, 3x 12-bit ADC, 16x controllable PWM channels
On-chip accurate clock and timer
Temperature sensor
On-chip accelerated floating point libraries
8x programmable IO (PIO) state machines for custom peripherals
Why a Raspberry Pi Pico?
Designing your own microcontroller instead of buying an existing one brings a number of advantages. According to Raspberry Pi itself, not one of the existing products available for this comes close to their price/performance ratio.
This Raspberry Pi Pico has also given Raspberry Pi the ability to add some innovative and powerful features of their own. These features are not available anywhere else.
A third reason is that the Raspberry Pi Pico has given Raspberry Pi the ability to create powerful software around the product. Surrounding this software stack is an extensive documentation set. The software and documentation meet the high standard of Raspberry Pi's core products (such as the Raspberry Pi 400, Pi 4 Model B and Pi 3 Model A+).
Who is this microcontroller for?
The Raspberry Pi Pico is suitable for both advanced and novice users. From controlling a display to controlling many different devices that you use every day. Automating everyday operations is made possible by this technology.
Beginner users
The Raspberry Pi Pico is programmable in the C and MicroPython languages and is customizable for a wide range of devices. In addition, the Pico is as easy to use as dragging and dropping files. This makes this microcontroller ideally suited for the novice user.
Advanced users
For advanced users, it is possible to take advantage of the Pico's extensive peripherals. The peripherals include the SPI, I²C, and eight programmable I/O (PIO)-state machines.
What makes the Raspberry Pi Pico unique?
What's unique about the Pico is that it was developed by Raspberry Pi itself. The RP2040 features a dual-core Arm Cortex-M0+ processor with 264 KB of internal RAM and support for up to 16 MB of off-chip Flash.
The Raspberry Pi Pico is unique for several reasons:
The product has the highest price/quality ratio in the microcontroller board market.
The Raspberry Pi Pico has been developed by Raspberry Pi itself.
The software stack surrounding this product is of high quality and comes paired with a comprehensive documentation set.
ESP32-C3-DevKitM-1 is an entry-level development board based on ESP32-C3-MINI-1, a module named for its small size. This board integrates complete Wi-Fi and Bluetooth LE functions. Most of the I/O pins on the ESP32-C3-MINI-1 module are broken out to the pin headers on both sides of this board for easy interfacing. Developers can either connect peripherals with jumper wires or mount ESP32-C3-DevKitM-1 on a breadboard. Specifications ESP32-C3-MINI-1 ESP32-C3-MINI-1 is a general-purpose Wi-Fi and Bluetooth LE combo module that comes with a PCB antenna. At the core of this module is ESP32-C3FN4, a chip that has an embedded flash of 4 MB. Since flash is packaged in the ESP32-C3FN4 chip, rather than integrated into the module, ESP32-C3-MINI-1 has a smaller package size. 5 V to 3.3 V LDO Power regulator that converts a 5 V supply into a 3.3 V output. 5 V Power On LED Turns on when the USB power is connected to the board. Pin Headers All available GPIO pins (except for the SPI bus for flash) are broken out to the pin headers on the board. For details, please see Header Block. Boot Button Download button. Holding down Boot and then pressing Reset initiates Firmware Download mode for downloading firmware through the serial port. Micro-USB Port USB interface. Power supply for the board as well as the communication interface between a computer and the ESP32-C3FN4 chip. Reset Button Press this button to restart the system. USB-to-UART Bridge Single USB-UART bridge chip provides transfer rates up to 3 Mbps. RGB LED Addressable RGB LED, driven by GPIO 8. Downloads ESP32-C3 Datasheet ESP32-C3-MINI-1 Datasheet ESP32-C3-DevKitM-1 Schematic ESP32-C3-DevKitM-1 PCB Layout ESP32-C3-DevKitM-1 Dimensions
The nRF52840 dongle is a small, low-cost USB dongle that supports Bluetooth 5.3, Bluetooth mesh, Thread, ZigBee, 802.15.4, ANT and 2.4 GHz proprietary protocols. The dongle is the perfect target hardware for use with nRF Connect for Desktop as it is low-cost but still support all the short range wireless standards used with Nordic devices.
The dongle has been designed to be used as a wireless HW device together with nRF Connect for Desktop. For other use cases please do note that there is no debug support on the dongle, only support for programming the device and communicating through USB.
It is supported by most of the nRF Connect for Desktop apps and will automatically be programmed if needed. In addition custom applications can be compiled and downloaded to the dongle. It has a user programmable RGB LED, a green LED, a user programmable button as well as 15 GPIO accessible from castellated solder points along the edge. Example applications are available in the nRF5 SDK under the board name PCA10059.
The nRF52840 dongle is supported by nRF Connect for Desktop as well as programming through nRFUtil.
Features
Bluetooth 5.2 ready multiprotocol radio
2 Mbps
Long Range
Advertising Extensions
Channel Selection Algorithm #2 (CSA #2)
IEEE 802.15.4 radio support
Thread
ZigBee
Arm Cortex-M4 with floating point support
DSP instruction set
ARM CryptoCell CC310 cryptographic accelerator
15 GPIO available via edge castellation
USB interface direct to nRF52840 SoC
Integrated 2.4 GHz PCB antenna
1 user-programmable button
1 user-programmable RGB LED
1 user-programmable LED
1.7-5.5 V operation from USB or external
Downloads
Datasheet
Hardware Files
Features RP2040 microcontroller with 2 MB Flash Dual-core cortex M0+ at up to 133 MHz 264 KB multi-bank high performance SRAM External Quad-SPI Flash with eXecute In Place (XIP) High performance full-crossbar bus fabric 30 multi-function General Purpose IO (4 can be used for ADC) 1.8-3.3 V IO Voltage (NOTE. Pico IO voltage is fixed at 3.3 V) 12-bit 500 ksps Analogue to Digital Converter (ADC) Various digital peripherals 2× UART, 2× I²C, 2× SPI, 16× PWM channels 1× Timer with 4 alarms, 1× Real Time Counter 2× Programmable IO (PIO) blocks, 8 state machines total Flexible, user-programmable high-speed IO Can emulate interfaces such as SD Card and VGA Includes W5100S Supports Hardwired Internet Protocols: TCP, UDP, WOL over UDP, ICMP, IGMPv1/v2, IPv4, ARP, PPPoE Supports 4 Independent Hardware SOCKETs simultaneously Internal 16 KB Memory for TX/ RX Buffers SPI Interface Micro-USB B port for power and data (and for reprogramming the Flash) 40 pin 21x51 'DIP' style 1mm thick PCB with 0.1' through-hole pins also with edge castellations 3-pin ARM Serial Wire Debug (SWD) port 10 / 100 Ethernet PHY embedded Supports Auto Negotiation Full / Half Duplex 10 / 100 Based Built-in RJ45 (RB1-125BAG1A) Built-in LDO (LM8805SF5-33V) Downloads RP2040 Datasheet W5100S Datasheet Schematic & Part list & Gerber File C/C++ Examples CircuitPython Examples
Arduino Uno is an open-source microcontroller board based on the ATmega328P. It has 14 digital input/output pins (of which 6 can be used as PWM outputs), 6 analog inputs, a 16 MHz ceramic resonator (CSTCE16M0V53-R0), a USB connection, a power jack, an ICSP header and a reset button. It contains everything needed to support the microcontroller; simply connect it to a computer with a USB cable or power it with a AC-to-DC adapter or battery to get started. You can tinker with your Uno without worring too much about doing something wrong, worst case scenario you can replace the chip for a few dollars and start over again.
'Uno' means one in Italian and was chosen to mark the release of Arduino Software (IDE) 1.0. The Uno board and version 1.0 of Arduino Software (IDE) were the reference versions of Arduino, now evolved to newer releases. The Uno board is the first in a series of USB Arduino boards, and the reference model for the Arduino platform; for an extensive list of current, past or outdated boards see the Arduino index of boards.
Specifications
Microcontroller
ATmega328P
Operating Voltage
5 V
Input Voltage (recommended)
7-12 V
Input Voltage (limit)
6-20 V
Digital I/O Pins
14 (of which 6 provide PWM output)
PWM Digital I/O Pins
6
Analog Input Pins
6
DC Current per I/O Pin
20 mA
DC Current for 3.3 V Pin
50 mA
Flash Memory
32 KB (ATmega328P) of which 0.5 KB used by bootloader
SRAM
2 KB (ATmega328P)
EEPROM
1 KB (ATmega328P)
Clock Speed
16 MHz
LED_BUILTIN
13
Dimensions
68.6 x 53.4 mm
Weight
25 g
The Uno R3 board is the perfect microcontroller for those who want to enter the programming world without any fuss. Its ATMega328 microcontroller provides you with enough power for your ideas and projects. The Uno board has a USB type B connector so that you can easily use it with programs – of course via the well-known programming environment Arduino IDE. You can connect it to the power source via the USB port or alternatively use its own power connection. Please note: The CH341 driver must be installed beforehand so that Uno board is recognized by the Arduino IDE. Microcontroller ATmega 328 Clock speed 16 MHz Operating voltage 5 V Input voltage 5-10 V Digital I/O Pins 14 with PWM 6 USB 1x SPI 1x I²C 1x ICSP 1x Flash Memory 32 KB EEPROM 1x
This ESP32 terminal is a microcontroller based on the ESP32 master. It adopts Xtensa 32-bit LX7 dual-core processor with a main frequency of up to 240 Mhz, supports 2.4 GHz Wi-Fi and Bluetooth 5 (LE), and can easily handle common edge terminal device application scenarios, such as industrial control, agricultural production environment detection and processing, intelligent logistics monitoring, smart home scenarios and more.
The ESP32 module also has a 3.5-inch parallel RGB interface capacitive touch screen with a resolution of 320x480 to ensure perfect image output at a frame rate 60 FPS. The 4 Crowtail interfaces on the back of this terminal can be used with Crowtail series sensors, plug and play, and create more interesting projects quickly and conveniently. In addition, it is also equipped with an SD card slot for extended storage (SPI leads) and a buzzer function.
The ESP32 touchscreen supports ESP-IDF and Arduino IDE development and is compatible with Python/MicroPython/Arduino. It also supports LVGL, which is the most popular free and open-source embedded graphics library to create beautiful UIs for any MCU, MPU, and display type. Now it has also obtained the official certification of LVGL. LVGL's board certificate shows that the boards can be easily used with LVGL and has decent performance for UI applications. The onboard charging circuit and lithium battery interface can use the type-C power supply interface to supply power and charge the battery at the same time, providing more outdoor scene expansion possibilities.
Features
Integrated ESP32-S3 module, which is support 2.4 GHz Wi-Fi and Bluetooth 5 (LE)
LCD 3.5 inches parallel TFT-LCD with 320x480 resolution
Compatible with Arduino/Python/MicrmoPython
Mature software support, support ESP-IDF and Arduino IDE development
Support open-source Graphics Library-LVGL
Support 1T1R mode, data rate up to 150 Mbps, Wireless Multimedia (WMM)
Perfect security mechanism, support AES-128/256, Hash, RSA, HMAC, digital signatures and secure boot
Onboard charging chip and interface, use type-C interface to charge
With 4 Crowtail interfaces (HY2.0-4P connector), plug and play with various Crowtail sensor
Applications
Smart Home
Industrial Control
Medical Monitor
Home Appliance Display
Logistics Monitoring
Specifications
ESP32-S3 module with 16 MB Flash and 8 MB PSRAM
Wi-Fi Protocol: 802.11b/g/n (802.11n up to 150 Mbps) Wi-Fi Frequency Range: 2.402-2.483 Ghz
Support Bluetooth 5
With 4 Crowtail interfaces (HY2.0-4P connector) and onboard Micro TF card slot
3.5-inch TFT LCD RGB true color LCD screen with 320x480 resolution
Driver chip: ILI9488 (16-bit parallel line)
Capacitive touch panel controller IC FT6236 series
Operating Voltage: DC 5 V-500 mA
Sleep current:
USB power supply: 6.86 mA
Lithium battery power supply: 3.23 mA
LiPo Battery Interface: PH2.0
Operating temperature: -10°C ~ 65°C
Active Area: 73.63 x 49.79 mm (L x W)
Dimensions: 106 x 66 x 13 mm (L x W x H)
Included
1x 3.5-inch ESP RGB Display with Acrylic Shell
1x USB-C Cable
Downloads
Wiki
Schematic Diagram
16 learning Lessons for LVGL
Source code
Lesson code
LVGL Reference
ESP32-S3 Datasheet
ILI9488 Datasheet
Capacitive Touch Display Data
T-PicoC3 is LILYGO's first motherboard with dual MCUs – equipped with Raspberry Pi RP2040 and ESP32-C3 chip (supporting WiFi and Bluetooth).Specifications
MCU
RP2040 Dual ARM Cortex-M0+
Flash
4 MB
Programming language
C/C++, MicroPython
Support machine leraning library
TensorFlow Lite
Onboard functions
Buttons: IO06+IO07, battery power detection
1.14 inch ST7789V IPS LCD
Resolution
135 x 240
Display
Full-color TFT
Interface
4-Wire SPI
Power supply
3.3 V
Operating temperature
-20~70°C
Dimensions
2.4 x 5.3 cm (W x H)
DownloadsGitHub
The ESP32-S3-DevKitC-1 is an entry-level development board equipped with ESP32-S3-WROOM-1U, a general-purpose Wi-Fi + Bluetooth Low Energy MCU module that integrates complete Wi-Fi and Bluetooth Low Energy functions.
Most of the I/O pins on the module are broken out to the pin headers on both sides of this board for easy interfacing. Developers can either connect peripherals with jumper wires or mount ESP32-S3-DevKitC-1 on a breadboard.
Features
Module integrated: ESP32-S3-WROOM-1U-N8R8
Flash: 8 MB QD
PSRAM: 8 MB OT
SPI voltage: 3.3 V
Specifications
ESP32-S3-WROOM-1U
ESP32-S3-WROOM-1U is a powerful, generic Wi-Fi + Bluetooth Low Energy MCU module that has a rich set of peripherals. It provides acceleration for neural network computing and signal processing workloads. ESP32-S3-WROOM-1U comes with an external antenna connector.
5 V to 3.3 V LDO
Power regulator that converts a 5 V supply into a 3.3 V output.
Pin Headers
All available GPIO pins (except for the SPI bus for flash) are broken out to the pin headers on the board for easy interfacing and programming.
USB-to-UART Port
A Micro-USB port used for power supply to the board, for flashing applications to the chip, as well as for communication with the chip via the on-board USB-to-UART bridge.
Boot Button
Download button. Holding down Boot and then pressing Reset initiates Firmware Download mode for downloading firmware through the serial port.
Reset Button
Press this button to restart the system.
USB Port
ESP32-S3 full-speed USB OTG interface, compliant with the USB 1.1 specification. The interface is used for power supply to the board, for flashing applications to the chip, for communication with the chip using USB 1.1 protocols, as well as for JTAG debugging.
USB-to-UART Bridge
Single USB-to-UART bridge chip provides transfer rates up to 3 Mbps.
RGB LED
Addressable RGB LED, driven by GPIO38.
3.3 V Power On LED
Turns on when the USB power is connected to the board.
Downloads
Pinout
GreatFET One is a hardware hacker’s best friend. With an extensible, open source design, two USB ports, and 100 expansion pins, GreatFET One is your essential gadget for hacking, making, and reverse engineering. By adding expansion boards called neighbors, you can turn GreatFET One into a USB peripheral that does almost anything.Whether you need an interface to an external chip, a logic analyzer, a debugger, or just a whole lot of pins to bit-bang, the versatile GreatFET One is the tool for you. Hi-Speed USB and a Python API allow GreatFET One to become your custom USB interface to the physical world.Features
Serial protocols: SPI, I²C, UART, and JTAG
Programmable digital I/O
Analog I/O (ADC/DAC)
Logic analysis
Debugging
Data acquisition
Four LEDs
Versatile USB functions
High-throughput hardware-assisted streaming serial engine
Downloads
Documentation
GitHub
BeagleY-AI is a low-cost, open-source, and powerful 64-bit quad-core single-board computer, equipped with a GPU, DSP, and vision/deep learning accelerators, designed for developers and makers.
Users can take advantage of BeagleBoard.org's provided Debian Linux software images, which include a built-in development environment. This enables the seamless running of AI applications on a dedicated 4 TOPS co-processor, while simultaneously handling real-time I/O tasks with an 800 MHz microcontroller.
BeagleY-AI is designed to meet the needs of both professional developers and educational environments. It is affordable, easy to use, and open-source, removing barriers to innovation. Developers can explore in-depth lessons or push practical applications to their limits without restriction.
Specifications
Processor
TI AM67 with quad-core 64-bit Arm Cortex-A53, GPU, DSP, and vision/deep learning accelerators
RAM
4 GB LPDDR4
Wi-Fi
BeagleBoard BM3301 module based on TI CC3301 (802.11ax Wi-Fi)
Bluetooth
Bluetooth Low Energy 5.4 (BLE)
USB
• 4x USB-A 3.0 supporting simultaneous 5 Gbps operation• 1x USB-C 2.0 supports USB 2.0 device
Ethernet
Gigabit Ethernet, with PoE+ support (requires separate PoE+ HAT)
Camera/Display
1x 4-lane MIPI camera/display transceivers, 1x 4-lane MIPI camera
Display Output
1x HDMI display, 1x OLDI display
Real-time Clock (RTC)
Supports an external button battery for power failure time retention. It is only populated on EVT samples.
Debug UART
1x 3-pin debug UART
Power
5 V/5 A DC power via USB-C, with Power Delivery support
Power Button
On/Off included
PCIe Interface
PCI-Express Gen3 x1 interface for fast peripherals (requires separate M.2 HAT or other adapter)
Expansion Connector
40-pin header
Fan connector
1x 4-pin fan connector, supports PWM speed control and speed measurement
Storage
microSD card slot, with support for high-speed SDR104 mode
Tag Connect
1x JTAG, 1x Tag Connect for PMIC NVM Programming
Downloads
Pinout
Documentation
Quick start
Software
The T-Journal is a cheap ESP32 Camera Development Board that features an OV2640 camera, an antenna, a 0.91 inch OLED display, some exposed GPIOs, and a micro-USB interface. It makes it easy and quick to upload code to the board. Specifications Chipset Expressif-ESP32-PCIO-D4 240 MHz Xtensa single-/dual-core 32-bit LX6 microprocessor FLASH QSPI flash/SRAM, up to 4x 16 MB SRAM 520 kB SRAM KEY reset, IO32 Display 0.91' SSD1306 Power indicator lamp red USB to TTL CP2104 Camera OV2640, 2 Megapixel Steering engine analog servo On-board clock 40 MHz crystal oscillator Working voltage 2.3-3.6 V Working current about 160 mA Working temperature range -40℃ ~ +85℃ Size 64.57 x 23.98 mm Power Supply USB 5 V/1 A Charging current 1 A Battery 3.7 V lithium battery WiFi Standard FCC/CE/TELEC/KCC/SRRC/NCC (ESP32-chip) Protocol 802.11 b/g/n/e/i (802.11n, speed up to 150 Mbps) A-MPDU and A-MSDU polymerization, support 0.4 μS Protection interval Frequency range 2.4 GHz~2.5 GHz (2400 M ~ 2483.5 M) Transmit Power 22 dBm Communication distance 300m Bluetooth Protocol meet bluetooth v4.2BR/EDR and BLE standard Radio frequency with -98 dBm sensitivity NZIF receiver Class-1, Class-2 & Class-3 emitter AFH Audio frequency CVSD & SBC audio frequency Software Wifi Mode Station/SoftAP/SoftAP+Station/P2P Security mechanism WPA/WPA2/WPA2-Enterprise/WPS Encryption Type AES/RSA/ECC/SHA Firmware upgrade UART download/OTA (Through network/host to download and write firmware) Software Development Support cloud server development /SDK for user firmware development Networking protocol IPv4, IPv6, SSL, TCP/UDP/HTTP/FTP/MQTT User Configuration AT + Instruction set, cloud server, Android/iOS app OS FreeRTOS Included 1x ESP32 Camera Module (Fish-eye Lens) 1x Wi-Fi Antenna 1x Power Line Downloads Camera library for Arduino
ESP32-S3-GEEK is a geek development board with built-in USB-A port, 1.14-inch LCD screen, TF card slot and other peripherals. It supports 2.4 GHz WiFi and BLE 5, with built-in 16 MB Flash & 2 MB PSRAM, provides I²C port, UART port and GPIO header for more possibilities for your project.
Features
Adopts ESP32-S3R2 chip with Xtensa 32-bit LX7 dual-core processor, capable of running at 240 MHz
Built in 512 KB SRAM, 384 KB ROM, 2 MB of on-chip PSRAM, and onboard 16 MB Flash memory
Onboard 1.14-inch 240x135 pixels 65K color IPS LCD display
Integrated 2.4 GHz WiFi and Bluetooth LE wireless communication
WiFi supports Infrastructure BSS in Station, SoftAP, and Station + SoftAP modes
WiFi supports 1T1R mode with data rate up to 150 Mbps
Bluetooth supports high power mode (20 dBm)
Internal co-existence mechanism between Wi-Fi and Bluetooth to share the same antenna
Onboard 3-pin UART port, 3-pin GPIO header and 4-pin I²C port
Equipped with plastic case and cables
Provides online open-source demo and resources, more convenient for learning and development
Dimensions: 61.0 x 24.5 x 9.0 mm
Downloads
Wiki
Features Piezo Buzzer: Acts as a simple audio output Micro USB Port Programmable Button 12 x LED: Provides visual output on board Specifications Microcontroller ATmega328P Programming IDE Arduino IDE Operating Voltage 5 V Digital I/O 20 PWM 6 Analog Input 6 (10-bit) UART 1 SPI 1 I2C 1 External Interrupt 2 Flash Memory 32 KB SRAM 2 KB EEPROM / Data Flash 1 KB Clock Speed 16 MHz DC Current I/O Pin 20 mA Power Supply USB only DC Current for 5 V USB Source DC Current for 3.3 V 500 mA USB to Serial Chip CH340G Programmable LED 12 at digital Pin 2 to 13 Programmable Push Button 1 at digital Pin 2 Piezo Buzzer 1 at digital Pin 8 Arduino vs Maker Uno
Features Build in USB to Serial interface Build-in PCB antenna Powered by Pineseed BL602 SoC using Pinenut model: 12S stamp 2 MB Flash USB-C connection Suitable to breadboard BIY project On board three color LEDs output Dimensions: 25.4 x 44.0 mm Note: USB cable is not included.
SwiftIO offers a full Swift compiler and framework environment that runs on the microcontroller. The SwiftIO board is a compact electronic circuit board that runs Swift on the bare metal, giving you a system that can be used to control all kinds of electronic projects.
Features
NXP i.MX RT1052 Crossover Processor with ARM Cortex-M7 core @ 600 MHz
8 MB SPI Flash, 32 MB SDRAM
On-board DAPLink debugger
On-board USB to UART for serial communication
On-board RGB LED
On-board SD socket
46x GPIO, 12x ADC, 14x PWM, 4x UART, 2x I²C, 2x SPI etc.
Many additional advanced features to meet the needs of advanced users
Zephyr RTOS support
MadMachine IDE is the premier integrated development environment for SwiftIO, which makes it easy to write Swift code and download it to the board.
Features
Nordic nRF52840 Bluetooth LE processor – 1 MB of Flash, 256KB RAM, 64 MHz Cortex M4 processor
1.3″ 240×240 Color IPS TFT display for high-resolution text and graphics
Power it from any 3-6V battery source (internal regulator and protection diodes)
Two A / B user buttons and one reset button
ST Micro series 9-DoF motion – LSM6DS33 Accel/Gyro + LIS3MDL magnetometer
APDS9960 Proximity, Light, Color, and Gesture Sensor
PDM Microphone sound sensor
SHT Humidity
BMP280 temperature and barometric pressure/altitude
RGB NeoPixel indicator LED
2 MB internal flash storage for datalogging, images, fonts or CircuitPython code
Buzzer/speaker for playing tones and beeps
Two bright white LEDs in front for illumination / color sensing
Qwiic / STEMMA QT connector for adding more sensors, motor controllers, or displays over I²C. You can plug in GROVE I²C sensors by using an adapter cable.
Programmable with Arduino IDE or CircuitPython
The AVR-IoT WA development board combines a powerful ATmega4808 AVR MCU, an ATECC608A CryptoAuthentication secure element IC and the fully certified ATWINC1510 Wi-Fi network controller – which provides the most simple and effective way to connect your embedded application to Amazon Web Services (AWS). The board also includes an on-board debugger, and requires no external hardware to program and debug the MCU.
Out of the box, the MCU comes preloaded with a firmware image that enables you to quickly connect and send data to the AWS platform using the on-board temperature and light sensors. Once you are ready to build your own custom design, you can easily generate code using the free software libraries in Atmel START or MPLAB Code Configurator (MCC).
The AVR-IoT WA board is supported by two award-winning Integrated Development Environments (IDEs) – Atmel Studio and Microchip MPLAB X IDE – giving you the freedom to innovate with your environment of choice.
Features
ATmega4808 microcontroller
Four user LED’s
Two mechanical buttons
mikroBUS header footprint
TEMT6000 Light sensor
MCP9808 Temperature sensor
ATECC608A CryptoAuthentication™ device
WINC1510 WiFi Module
On-board Debugger
Auto-ID for board identification in Atmel Studio and Microchip MPLAB X
One green board power and status LED
Programming and debugging
Virtual COM port (CDC)
Two DGI GPIO lines
USB and battery powered
Integrated Li-Ion/LiPo battery charger
ESP32-S2-Saola-1R is a small-sized ESP32-S2 based development board. Most of the I/O pins are broken out to the pin headers on both sides for easy interfacing. Developers can either connect peripherals with jumper wires or mount ESP32-S2-Saola-1R on a breadboard.ESP32-S2-Saola-1R is equipped with the ESP32-S2-WROVER module, a powerful, generic Wi-Fi MCU module that has a rich set of peripherals. It is an ideal choice for a wide variety of application scenarios relating to Internet of Things (IoT), wearable electronics and smart home. The board a PCB antenna and features a 4 MB external SPI flash and an additional 2 MB SPI Pseudo static RAM (PSRAM).FeaturesMCU
ESP32-S2 embedded, Xtensa® single-core 32-bit LX7 microprocessor, up to 240 MHz
128 KB ROM
320 KB SRAM
16 KB SRAM in RTC
WiFi
802.11 b/g/n
Bit rate: 802.11n up to 150 Mbps
A-MPDU and A-MSDU aggregation
0.4 µs guard interval support
Center frequency range of operating channel: 2412 ~ 2484 MHz
Hardware
Interfaces: GPIO, SPI, LCD, UART, I²C, I²S, Camera interface, IR, pulse counter, LED PWM, TWAI (compatible with ISO 11898-1), USB OTG 1.1, ADC, DAC, touch sensor, temperature sensor
40 MHz crystal oscillator
4 MB SPI flash
Operating voltage/Power supply: 3.0 ~ 3.6 V
Operating temperature range: –40 ~ 85 °C
Dimensions: 18 × 31 × 3.3 mm
Applications
Generic Low-power IoT Sensor Hub
Generic Low-power IoT Data Loggers
Cameras for Video Streaming
Over-the-top (OTT) Devices
USB Devices
Speech Recognition
Image Recognition
Mesh Network
Home Automation
Smart Home Control Panel
Smart Building
Industrial Automation
Smart Agriculture
Audio Applications
Health Care Applications
Wi-Fi-enabled Toys
Wearable Electronics
Retail & Catering Applications
Smart POS Machines
PÚCA DSP is an open-source, Arduino-compatible ESP32 development board for audio and digital signal processing (DSP) applications with expansive audio-processing features. It provides audio inputs, audio outputs, a low-noise microphone array, an integrated test-speaker option, additional memory, battery-charge management, and ESD protection all on a small, breadboard-friendly PCB.
Synthesizers, Installations, Voice UI, and More
PÚCA DSP can be used for a wide range of DSP applications, including but not limited to those in the fields of music, art, creative technology, and adaptive technology. Music-related examples include digital-music synthesis, mobile recording, Bluetooth speakers, wireless line-level directional microphones, and the design of smart musical instruments. Art-related examples include acoustic sensor networks, sound-art installations, and Internet-radio applications. Examples related to creative and adaptive technology include voice user interface (VUI) design and Web audio for the Internet of Sounds.
Compact, Integrated Design
PÚCA DSP was designed for portability. When used with an external 3.7 V rechargeable battery, it can be deployed almost anywhere or integrated into just about any device, instrument, or installation. Its design emerged from months of experimentation with various ESP32 development boards, DAC breakout boards, ADC breakout boards, Microphone breakout boards, and audio-connector breakout boards, and – despite its diminutive size – it manages to provide all of that functionality in a single board. And it dos so without compromising signal quality.
Specifications
Processor & Memory
Espressif ESP32 Pico D4 Processor
32-bit dual core 80 MHz / 160 MHz / 240 MHz
4 MB SPI Flash with 8 MB additional PSRAM (Original Edition)
Wireless 2.4 GHz Wi-Fi 802.11b/g/n
Bluetooth BLE 4.2
3D Antenna
Audio
Wolfson WM8978 Stereo Audio Codec
Audio Line In on 3.5 mm stereo onnector
Audio Headphone / Line Out on 3.5 mm stereo connector
Stereo Aux Line In, Audio Mono Out routed to GPIO Header
2x Knowles SPM0687LR5H-1 MEMS Microphones
ESD protection on all audio inputs and outputs
Support for 8, 11.025, 12, 16, 22.05, 24, 32, 44.1 and 48 kHz sample rates
1 W Speaker Driver, routed to GPIO Header
DAC SNR 98 dB, THD -84 dB (‘A’ weighted @ 48 kHz)
ADC SNR 95 dB, THD -84 dB (‘A’ weighted @ 48 kHz)
Line input impedance: 1 MOhm
Line output impedance: 33 Ohm
Form Factor and Connectivity
Breadboard friendly
70 x 24 mm
11x GPIO pins broken out to 2.54 mm pitch header, with access to both ESP32 ADC channels, JTAG and capacitive touch pins
USB 2.0 over USB Type C connector
Power
3.7/4.2 V Lithium Polymer Rechargeable Battery, USB or external 5 V DC power source
ESP32 and Audio Codec can be placed into low power modes under software control
Battery voltage level detection
ESD protection on USB data bus
Downloads
GitHub
Datasheet
Links
Crowd Supply Campaign (includes FAQs)
Hardware Overview
Programming the Board
The Audio Codec
The SparkFun RedBoard Qwiic is an Arduino-compatible board that combines features of different Arduinos with the Qwiic Connect System.
Features
ATmega328 microcontroller with Optiboot Bootloader
R3 Shield Compatible
CH340C Serial-USB Converter
3.3 V to 5 V Voltage Level Jumper
A4 / A5 Jumpers
AP2112 Voltage Regulator
ISP Header
Input voltage: 7 V - 15 V
1 Qwiic Connector
16 MHz Clock Speed
32 k Flash Memory
All SMD Construction
Improved Reset Button
ATOM U is a compact low-power consumption speech recognition IoT development kit. It adopts an ESP32 chipset, equipped with 2 low-power Xtensa 32-bit LX6 microprocessors with the main frequency of up to 240 MHz. Built-in USB-A interface, IR emitter, programmable RGB LED. Plug-and-play, easy to upload and download programs. Integrated Wi-Fi and digital microphone SPM1423 (I2S) for the clear sound record. suitable for HMI, Speech-to-Text (STT). Low-code development ATOM U supports UIFlow graphical programming platform, scripting-free, cloud push; Fully compatible with Arduino, MicroPython, ESP32-IDF, and other mainstream development platforms, to quickly build various applications. High integration ATOM U contains a USB-A port for programming/power supply, IR emitter, programmable RGB LED x1, button x1; Finely tuned RF circuit, providing stable and reliable wireless communication. Strong expandability ATOM U is easy access to M5Stack's hardware and software system. Features ESP32-PICO-D4 (2.4GHz Wi-Fi dual mode) Integrated programmable RGB LED and button Compact design Built-in IR emitter Expandable pinout and GROVE port Development platform: UIFlow MicroPython Arduino Specifications ESP32-PICO-D4 240MHz dual core, 600 DMIPS, 520KB SRAM, 2.4G Wi-Fi Microphone SPM1423 Microphone sensitivity 94 dB SPL@1 KHz Typical value: -22 dBFS Microphone signal-to-noise ratio 94 dB SPL@1 KHz, A-weighted Typical value: 61.4 dB Standby working current 40.4 mA Support input sound frequency 100 Hz ~ 10 KHz Support PDM clock frequency 1.0 ~ 3.25 MHz Weight 8.4 g Product size 52 x 20 x 10 mm Downloads Documentation
Waveshare RP2040-PiZero is a high-performance and cost-effective microcontroller board with onboard DVI interface, TF card slot and PIO-USB port, compatible with Raspberry Pi 40-pin GPIO header, easy to develop and integrate into the products.
Features
RP2040 microcontroller chip designed by Raspberry Pi
Dual-core ARM Cortex M0+ processor, flexible clock running up to 133 MHz
264 KB of SRAM, and 16 MB of onboard Flash memory
Onboard DVI interface can drive most HDMI screens (DVI compatibility required)
Supports using as a USB host or slave via onboard PIO-USB port
Onboard TF card slot for reading and writing TF card
Onboard Lithium battery recharge/discharge header, suitable for mobile scenarios
USB 1.1 with device and host support
Drag-and-drop programming using mass storage over USB
Low-power sleep and dormant modes
2x SPI, 2x I²C, 2x UART, 4x 12-bit ADC, 16x controllable PWM channels
Accurate clock and timer on-chip
Temperature sensor
Accelerated floating-point libraries on-chip
Downloads
Wiki
