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
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
If you want to enter the programming world quickly and easily, JOY-iT Mega 2560 R3 is the board for you. Due to the abundance of tutorials and instructions for this microcontroller online, you will start programming without any complications. Based on an ATmega2560, which offers sufficient power for your projects and ideas, JOY-iT Mega 2560 R3 has many connection options with 54 digital inputs and outputs and 16 analog inputs. To start programming your JOY-iT Mega 2560 R3, you need to install the development environment, and, of course, the drivers, on your computer. The Arduino IDE is best for using with the Mega 2560. This IDE is completely compatible with this board and offers you every driver you need for a quick start. Microcontroller ATmega2560 Clock speed 16 MHz Operating voltage 5 V/DC Digital I/O Pins 54 (of which 15 with PWM) Analog Input Pins 16 Analog Output Pins 15 Flash Memory 256 KB EEPROM 4 KB SRAM 8 KB Download JOY-iT Mega 2560 R3 Starter Kit here.
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
With the NodeMCU-ESP32, comfortable prototyping is possible with simple programming via Luascript or the Arduino IDE and the breadboard-compatible design. This board has 2.4 GHz dual-mode Wifi and a BT wireless connection. In addition, a 512 KB SRAM and a 4 MB memory are integrated on the microcontroller development board. The board has 21 pins for interface connection, including I²C, SPI, UART, DAC and ADC. Specifications Type ESP32 Processor Tensilica LX6 Dual-Core Clock Frequency 240 MHz SRAM 512 kB Memory 4 MB Wireless Lan 802.11 b/g/n Frequency 2.4 GHz Bluetooth Classic / LE Data Interfaces UART / I²C / SPI / DAC / ADC Operating Voltage 3.3 V (operable via 5 V microUSB) Operating Temperature –40°C – 125°C Dimensions 48 x 26 x 11.5 mm Weight 10 g Downloads Manual
Differences between micro:bit v1 and micro:bit v2 The BBC micro:bit v2 is equipped with BLE Bluetooth 5.0 It has a Power off button(push and hold power button) MEMS microphone with a LED indicator Onboard speaker Touch-sensitive logo pin LED power indicator A notched edge connector for easier connections.
The Coral USB Accelerator adds an Edge TPU coprocessor to your system, enabling high-speed machine learning inferencing on a wide range of systems, simply by connecting it to a USB port. Features Supported host OS: Debian Linux, macOS, Windows 10 Compatible with Raspberry Pi boards Supported Framework: TensorFlow Lite
Performs high-speed ML inferencing The on-board Edge TPU coprocessor is capable of performing 4 trillion operations (tera-operations) per second (TOPS), using 0.5 watts for each TOPS (2 TOPS per watt). For example, it can execute state-of-the-art mobile vision models such as MobileNet v2 at almost 400 FPS, in a power-efficient manner. Supports all major platforms Connects via USB to any system running Debian Linux (including Raspberry Pi), macOS, or Windows 10. Supports TensorFlow Lite No need to build models from the ground up. TensorFlow Lite models can be compiled to run on the Edge TPU. Supports AutoML Vision Edge Easily build and deploy fast, high-accuracy custom image classification models to your device with AutoML Vision Edge. Specifications ML accelerator Google Edge TPU coprocessor:4 TOPS (int8); 2 TOPS per watt Connector USB 3.0 Type-C (data/power) Dimensions 65 x 30 mm Downloads/Documentation Datasheet Get started with the USB Accelerator Model compatibility on the Edge TPU Edge TPU inferencing overview Run multiple models with multiple Edge TPUs Pipeline a model with multiple Edge TPUs PyCoral API (Python) Libcoral API (C++) Libedgetpu API (C++) Edge TPU compiler Pre-compiled models
All software downloads
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
LILYGO T-Display ESP32 WiFi and Bluetooth Module Development Board 1.14-inch LCD Control BoardSpecifications
Chipset
Espressif-ESP32 240 MHz Xtensa single-/dual-core 32-bit LX6 microprocessor
Flash
QSPI flash 16 MB
SRAM
520 kB SRAM
Button
Reset
USB to TTL
CP2104
Modular interface
UART, SPI, SDIO, I²C, LED PWM, TV PWM, I²S, IRGPIO, ADC, capacitor touch sensor, DACLNA pre-amplifier
Display
IPS ST7789V 1.14 Inch
Working voltage
2.7-4.2 V
Working current
About 67 MA
Sleep current
About 350 uA
Working temperature range
-40°C ~ +85°C
Size & Weight
51.52 x 25.04 x 8.54 mm (7.81 g)
Power Supply
USB 5 V/1 A
Charging current
500 mA
Battery
3.7 V lithium battery
JST Connector
2-Pin 1.25 mm
USB
Type-C
WiFi
Standard
FCC/CE-RED/IC/TELEC/KCC/SRRC/NCC (ESP32 chip)
Protocol
802.11 b/g/n (802.11n, speed up to 150 Mbps) A-MPDU and A-MSDU polymerization, support 0.4μS Protection interval
Frequency range
2.4~2.5 GHz (2400~2483.5 M)
Transmit Power
22 dBm
Communication distance
300 m
Bluetooth
Protocol
Meet bluetooth v4.2BR/EDR and BLE standard
Radio frequency
With -97 dBm sensitivity NZIF receiver Class-1, Class-2 & Class-3 emitter AFH
Audio frequency
CVSD&SBC audio frequency
Software
Wi-Fi 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 T-Display (16 MB)
1x Charging Cable
2x Pin
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
LoRa-E5 Development Kit is an easy-to-use compact development toolset for you to unlock the powerful performance of the LoRa-E5 STM32WLE5JC. It consists of a LoRa-E5 Dev Board, an antenna (EU868), a USB type C cable, and a 2-AA 3 V Battery Holder. LoRa-E5 Dev Board embedded with LoRa-E5 STM32WLE5JC Module, which is the world-first combo of LoRa RF and MCU chip into one single tiny chip and is FCC and CE certified. It is powered by ARM Cortex-M4 core and Semtech SX126X LoRa chip, supports both LoRaWAN and LoRa protocol on the worldwide frequency and (G)FSK, BPSK, (G)MSK, and LoRa modulations. The LoRa-E5 development board features a very long transmission range, extremely low power consumption and user-friendly interfaces. LoRa-E5 Dev Board has a long-distance transmission range of LoRa-E5 up to 10 km in an open area. The sleep current of LoRa-E5 modules on board is as low as 2.1 uA (WOR mode). It is designed with industrial standards with a wide working temperature at -40℃ ~ 85℃, high sensitivity between -116.5 dBm ~ -136 dBm, and power output up to +20.8 dBm at 3.3 V. LoRa-E5 Dev Board also has rich interfaces. Developed to unlock the full functionality of the LoRa-E5 module, LoRa-E5 Dev Board has led out full 28 pins of LoRa-E5 and provides with rich interfaces including Grove connectors, RS-485 terminal, male/female pin headers for you to connect sensors and modules with different connectors and data protocols, saving your time on wire soldering. You could also easily power the board by connecting the battery holder with 2-AA batteries, enabling temporary use when lacking an external power source. It is a user-friendly board for easy testing and rapid prototyping. Specifications Size LoRa-E5 Dev Board: 85.6 x 54 mm Voltage (supply) 3-5 V (Battery) / 5 V (USB-C) Voltage (output) EN 3V3 / 5 V Power (output) Up to +20.8 dBm at 3.3 V Frequency EU868 Protocol LoRaWAN Sensitivity -116.5 dBm ~ -136 dBm Interfaces USB Type C / JST2.0 / 3x Grove (2x I²C/1x UART) / RS485 / SMA-K / IPEX Modulation LoRa, (G)FSK, (G)MSK, BPSK Working temperature -40℃ ~ 85℃ Current LoRa-E5 module sleep current as low as 2.1 uA (WOR mode) Included 1x LoRa-E5 Dev Board 1x Antenna (EU868) 1x USB Type C Cable (20 cm) 1x 2-AA 3 V Battery Holder
The STM32 Nucleo board provides an affordable and flexible way for users to try out new ideas and build prototypes with any STM32 microcontroller line, choosing from the various combinations of performance, power consumption and features. The Arduino connectivity support and ST Morpho headers make it easy to expand the functionality of the STM32 Nucleo open development platform with a wide choice of specialised shields. The STM32 Nucleo board does not require any separate probe as it integrates the ST-LINK/V2-1 debugger and programmer. The STM32 Nucleo board comes with the STM32 comprehensive software HAL library together with various packaged software examples, as well as direct access to mbed online resources. Features STM32 microcontroller with LQFP64 package Two types of extension resources: Arduino Uno R3 connectivity STMicroelectronics Morpho extension pin headers for full access to all STM32 /Os mbed-enabled (http://mbed.org) On-board ST-LINK/V2-1 debugger/programmer with SWD connector – selection-mode switch to use the kit as a standalone ST-LINK/V2-1 Flexible board power supply – USB VBUS or external source (3.3 V, 5 V, 7 - 12 V) – Power management access point Three LEDs – USB communication (LD1), user LED (LD2), power LED (LD3) Two push buttons: USER and RESET USB re-enumeration capability: three different interfaces supported on USB – Virtual Com port – Mass storage – Debug port Supported by wide choice of Integrated Development Environments (IDEs) including IAR, Keil, GCC-based IDEs
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
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
WCH CH32V307 RISC-V development board features 8 UART ports controlled over Ethernet The CH32V307 is an interconnected microcontroller, based on 32-bit RISC-V core, with hardware stack area and fast interrupt entry. Compared with standard RISC-V, the interrupt response speed is greatly improved. With single-precision float point instruction sets added and stack area extended, the CH32V307 has higher performance, the number of U(S)ART is extended to 8, and the number of motor timer is extended to 4. The CH32V307 provides USB2.0 high-speed interface (480 Mbps) and has built-in PHY transceiver. Ethernet MAC is upgraded to GbE and integrates 10M PHY module. Features RISC-V4F processor, max 144 MHz system clock frequency Single-cycle multiplication and hardware division, hardware float point unit (FPU) 64KB SRAM, 256 KB Flash Supply voltage: 2.5 V/3.3 V, GPIO unit is supplied independently Multiple low-power modes: sleep/stop/standby Power-on/power-down reset (POR/PDR), programmable voltage detector (PVD) 2 general DMA controllers, 18 channels in total 4 amplifiers Single true random number generator (TRNG) 2x 12-bit DAC 2-unit 16-channel 12-bit ADC, 16-channel TouchKey 10 timers USB2.0 full-speed OTG interface USB2.0 high-speed host/device interface (built-in 480 Mbps PHY) 3 USARTs, 5 UARTs 2 CAN interfaces (2.0B active) SDIO interface, FSMC interface, DVP 2x I²C, 3x SPI, 2x I²S 80 I/O ports, can be mapped to 16 external interrupts CRC calculation unit, 96-bit unique chip ID Serial 2-wire debug interface Packages: LQFP64M, LQFP100 Downloads Datasheet GitHub
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
The Arduino Nano is a complete Arduino-compatible single board computer that can be plugged directly into a 32-pin socket, a breadboard or a corresponding carrier board. It offers the complete Arduino functionality in very compact dimensions. Via the micro-USB socket, you can supply the board and circuit with power as well as conveniently transfer new programs to the controller. Technical details Pin headers for direct use on the pinboard Ideal for prototyping Programmable via free Arduino IDE Connection via mini USB socket Chipset CH340G Interfaces: I²C, UART, SPI Size: 45 x 18 mm Microcontroller ATmega328P-AU Operating Voltage 5 V Flash Memory 32 KB (2 KB used for Bootloader) SRAM 2 KB EEPROM 1 KB Digital Pins 22 (6 with PWM) Analog Pins 8 DC Current per I/O Pin 40 mA Input Voltage 7-12 V Downloads Datasheet User Guide
LILYGO T-Display-GD32 RISC-V Development Board Specifications Chipset GD32VF103CBT6 FLASH 128 kB SRAM 32 kB On-board clock 108 MHz crystal oscillator Working Voltage 2.7 V - 3.6 V Button BOOT - RESET LCD ST7789 1.14' IPS 240 x 135 USB to TTL CP2104 Modular interface TIMER, UART, SPI, I2C, PWM, ADC, DAC, CAN, USBOTG Working Temperature Range -40 ~ +85°C Weight 10 g Size 51.49 mm x 25.2 mm x 10 mm Peripheral Button, RGB LED, SD slot, LCD Power Supply Input USB 5 V @ 1 A Charging Current 500 mA Battery Input 3.7-4.2 V USB USB-C Downloads GitHub
Portenta H7 follows the Arduino MKR form factor, but enhanced with the Portenta family 80-pin high-density connector. Program it with high-level languages and AI while performing low-latency operations on its customizable hardware. Portenta H7 simultaneously runs high level code along with real time tasks. The design includes two processors that can run tasks in parallel. For example, is possible to execute Arduino compiled code along with MicroPython one, and have both cores to communicate with one another. The Portenta functionality is two-fold, it can either be running like any other embedded microcontroller board, or as the main processor of an embedded computer. Portenta can easily run processes created with TensorFlow Lite, you could have one of the cores computing a computer vision algorithm on the fly, while the other could be making low-level operations like controlling a motor, or acting as a user interface. Use Portenta when performance is key, among other cases, we envision it to be part of: High-end industrial machinery Laboratory equipment Computer vision PLCs Industry-ready user interfaces Robotics controller Mission-critical devices Dedicated stationary computer High-speed booting computation (ms) Two Parallel Cores H7's main processor is the dual core STM32H747 including a Cortex M7 running at 480 MHz and a Cortex-M4 running at 240 MHz. The two cores communicate via a Remote Procedure Call mechanism that allows calling functions on the other processor seamlessly. Both processors share all the in-chip peripherals and can run: Arduino sketches on top of the ARM Mbed OS Native Mbed applications MicroPython / JavaScript via an interpreter TensorFlow Lite Graphics Accelerator Probably one of the most exciting features of the Portenta H7 is the possibility of connecting an external monitor to build your own dedicated embedded computer with a user interface. This is possible thanks to the STM32H747 processor's on-chip GPU, the Chrom-ART Accelerator. Besides the GPU, the chip includes a dedicated JPEG encoder and decoder. A new standard for pinouts The Portenta family adds two 80-pin high density connectors at the bottom of the board. This ensures scalability for a wide range of applications by simply upgrading your Portenta board to the one suiting your needs. On-board Connectivity The onboard wireless module allows to simultaneously manage WiFi and Bluetooth connectivity. The WiFi interface can be operated as an Access Point, as a Station or as a dual mode simultaneous AP/STA and can handle up to 65 Mbps transfer rate. Bluetooth interface supports Bluetooth Classic and Bluetooth Low Energy. It is also possible to expose a series of different wired interfaces like UART, SPI, or I²C, both through some of the MKR styled connectors, or through the new Arduino industrial 80-pin connector pair. The 80-pin connector pair provides additional features including Ethernet. USB-C Multipurpose Connector The board's programming connector is a USB-C port that can also be used to power the board, as a USB Hub, to connect a DisplayPort monitor, or to deliver power to OTG connected devices. Specifications The Arduino Portenta H7 is based on the STM32H747 microcontroller, XI series. Microcontroller STM32H747XI dual Cortex-M7+M4 32bit low power ARM MCU (datasheet)
Radio module Murata 1DX dual WiFi 802.11b/g/n 65 Mbps and Bluetooth (Bluetooth Low Energy. 5 via Cordio stack, Bluetooth Low Energy 4.2 via Arduino Stack) (datasheet) Secure element (default) NXP SE0502 (datasheet) Board power supply (USB/VIN) 5 V Supported battery Li-Po Single Cell, 3.7 V, 700 mAh Minimum (integrated charger) Circuit operating voltage 3.3 V Display connector MIPI DSI host & MIPI D-PHY to interface with low-pin count large display GPU Chrom-ART graphical hardware Accelerator Timers 22x timers and watchdogs UART 4x ports (2 with flow control) Ethernet PHY 10 / 100 Mbps (through expansion port only) SD card Interface for SD Card connector (through expansion port only) Operational temperature -40 °C to +85 °C MKR headers Use any of the existing industrial MKR shields on it High-density connectors Two 80-pin connectors will expose all of the board's peripherals to other devices Camera interface 8-bit, up to 80 MHz ADC 3x ADCs with 16-bit max. resolution (up to 36 channels, up to 3.6 MSPS) DAC 2x 12-bit DAC (1 MHz) USB-C Host / Device, DisplayPort out, High / Full Speed, Power delivery Downloads Datasheet Schematics Pinout
Ready to start developing Artificial Intelligence (AI) applications? The NVIDIA Jetson Nano Developer Kit makes the power of modern AI accessible to makers, developers, and students.
When you think of NVIDIA, you probably think about graphics cards and GPUs, and rightfully so. Nvidia's track record guarantees that the Jetson Nano has enough power to run even the most demanding of tasks.
The NVIDIA Jetson Nano Developer Kit is compatible with Nvidia's JetPack SDK and enables image classification and object detection amongst many applications.
Applications
The NVIDIA Jetson Nano Developer Kit can run multiple neural networks in parallel for applications like:
Image classification
Segmentation
Object detection
Speech processing
Specifications
GPU
128-core Maxwell
CPU
Quad-core ARM A57 @ 1.43 GHz
Memory
4 GB 64-bit LPDDR4 25.6 GB/s
Storage
microSD (not included)
Video Encode
4K @ 30 | 4x 1080p @ 30 | 9x 720p @ 30 (H.264/H.265)
Video Decode
4K @ 60 | 2x 4K @ 30 | 8x 1080p @ 30 | 18x 720p @ 30 (H.264/H.265)
Camera
1 x MIPI CSI-2 DPHY lanes
Connectivity
Gigabit Ethernet, M.2 Key E
Display
HDMI 2.0 and eDP 1.4
USB
4x USB 3.0, USB 2.0 Micro-B
Interfaces
GPIO, I²C, I²S, SPI, UART
Dimensions
100 x 80 x 29 mm
Included
NVIDIA Jetson Nano module and carrier board
Small paper card with quick start and support information
Folded paper stand
Downloads
JetPack SDK
Documentation
Tutorials
Online course
Wiki
