The Arduino Nano 33 BLE Sense Rev2 with headers is Arduino’s 3.3 V AI enabled board in the smallest available form factor with a set of sensors that will allow you without any external hardware to start programming your next project, right away.
With the Arduino Nano 33 BLE Sense Rev2, you can:
Build wearable devices that using AI can recognize movements.
Build a room temperature monitoring device that can suggest or modify changes in the thermostat.
Build a gesture or voice recognition device using the microphone or the gesture sensor together with the AI capabilities of the board.
Differences between Rev1 and Rev2
Replacement of IMU from LSM9DS1 (9 axis) for a combination of two IMUs (BMI270 – 6 axis IMU and BMM150 – 3 axis IMU)
Replacement of temperature and humidity sensor from HTS221 for HS3003
Replacement of microphone from MP34DT05 to MP34DT06JTR
Replacement of power supply MPM3610 for MP2322
Addition of VUSB soldering jumper on the top side of the board
New test point for USB, SWDIO and SWCLK
Specifications
Microcontroller
nRF52840 (datasheet)
Operating Voltage
3.3 V
Input Voltage (limit)
21 V
DC Current per I/O Pin
15 mA
Clock Speed
64 MHz
CPU Flash Memory
1 MB (nRF52840)
SRAM
256 KB (nRF52840)
EEPROM
None
Digital Input / Output Pins
14
PWM Pins
All digital pins
UART
1
SPI
1
I²C
1
Analog Input Pins
8 (ADC 12 bit 200 k samples)
Analog Output Pins
Only through PWM (no DAC)
External Interrupts
All digital pins
LED_BUILTIN
13
USB
Native in the nRF52840 Processor
IMU
BMI270 (datasheet) and BMM150 (datasheet)
Microphone
MP34DT06JTR (datasheet)
Gesture, light, proximity, color
APDS9960 (datasheet)
Barometric pressure
LPS22HB (datasheet)
Temperature, humidity
HS3003 (datasheet)
Downloads
Datasheet
Schematics
The JOY-iT JDS2960 is a 2-channel signal generator capable of producing signals up to 60 MHz. Its compact design and the option to operate it with a power bank make it ideal for mobile use.
With a variety of waveforms, including sine, square, triangle, pulse, half-wave, and more, it is suitable for various measurement technology applications.
Additionally, the JDS2960 features a 1-channel frequency allocation. Its high frequency accuracy of ±20 ppm and stability of ±1 ppm/3 h ensure excellent signal quality and great flexibility.
The 2.4-inch TFT color display provides user-friendly operation and enables a wide range of applications.
Features
2 Channels
Up to 60 MHz
Robust aluminum housing
1-channel frequency counter
Up to 20 Vpp
Many different pre-programmed waveforms and up to 60 user-defined waveforms
Pulse function
Specifications
Channels
2-channel Signal Generator1-channel Frequency meter
Frequency range
Sine: 0-60 MHzSquare, triangle: 0-25 MHzTTL, Pulse: 0-6 MHz
Signal forms
Sine, square, triangle, pulse, half/solid wave, exponential rise/fall, etc.
Measuring range frequency counter
1-100 MHz
Frequency accuracy
±20 ppm
Frequency stability
±1 ppm/3 h
Sampling rate
266 MSa/s
Display
2,4" TFT color LCD
Vertical shaft resolution
14 bits
Amplitude range
<10 MHz: 0-20 Vpp>10 MHz: 0-10 Vpp
Amplitude resolution
1 mV
Amplitude stability
±5%/5h
Amplitude flatness
<10 MHz: ±5%>10 MHz: ±10%
Impedance of output
50 Ω ±10%
Distortion factor
<0.8% (20 Hz-20 KHz, 0 dBm)
Dimensions
145 x 95 x 55 mm
Weight
900 g
Included
1x JOY-iT JDS2960 2-ch Signal Generator
1x Power supply unit
1x BNC-BNC cable
2x BNC crocodile clip cables
1x USB-DC power cable
1x USB data cable
Downloads
Datasheet
Manual
Software
The SparkFun RP2350 Pro Micro provides a powerful development platform, built around the RP2350 microcontroller. This board uses the updated Pro Micro form factor. It includes a USB-C connector, Qwiic connector, WS2812B addressable RGB LED, Boot and Reset buttons, resettable PTC fuse, and PTH and castellated solder pads.
The RP2350 is a unique dual-core microcontroller with two ARM Cortex-M33 processors and two Hazard3 RISC-V processors, all running at up to 150 MHz! Now, this doesn't mean the RP2350 is a quad-core microcontroller. Instead, users can select which two processors to run on boot instead. You can run two processors of the same type or one of each. The RP2350 also features 520 kB SRAM in ten banks, a host of peripherals including two UARTs, two SPI and two I²C controllers, and a USB 1.1 controller for host and device support.
The Pro Micro also includes two expanded memory options: 16 MB of external Flash and 8 MB PSRAM connected to the RP2350's QSPI controller. The RP2350 Pro Micro works with C/C++ using the Pico SDK, MicroPython, and Arduino development environments.
Features
RP2350 Microcontroller
8 MB PSRAM
16 MB Flash
Supply Voltage
USB: 5 V
RAW: 5.3 V (max.)
Pro Micro Pinout
2x UART
1x SPI
10x GPIO (4 used for UART1 and UART0)
4x Analog
USB-C Connector
USB 1.1 Host/Device Support
Qwiic Connector
Buttons
Reset
Boot
LEDs
WS2812 Addressable RGB LED
Red Power LED
Dimensions: 33 x 17.8 mm
Downloads
Schematic
Eagle Files
Board Dimensions
Hookup Guide
RP2350 MicroPython Firmware (Beta 04)
SparkFun Pico SDK Library
Arduino Pico Arduino Core
Datasheet (RP2350)
Datasheet (APS6404L PSRAM)
RP2350 Product Brief
Raspberry Pi RP2350 Microcontroller Documentation
Qwiic Info Page
GitHub Repository
GrovePi+ is stacked on top of the Raspberry Pi without the need for any other connections. Communication between the two occurs over the I²C interface. All Grove modules connect to the universal Grove connectors on the GrovePi+ shield via the universal 4-pin connector cable.
Grove modules work on analog and digital signals and can be connected directly to the ATMEGA328 microcontroller on the Grove Pi+. The microcontroller acts as an interpreter between the Raspberry Pi and the Grove sensors. It sends, receives, and executes commands sent by the Raspberry Pi.
Features
One GrovePi+ board together with 12 popular Grove sensors and 10 Grove cables
GrovePi+ is compatible with Raspberry Pi A+, B, B+ / 2, 3, 4.
CE certified and compatible with Linux and Win 10 IoT.
Included
1x Grove Pi+
1x Grove - Rotary Angle Sensor
1x Grove - Sound Sensor
1x Grove - LCD RGB Backlight
1x Grove - Temp&Humi Sensor
1x Grove - Red LED
1x Grove - Light Sensor
1x Grove - Buzzer
1x Grove - Relay
1x Grove - Blue LED
1x Grove - Button
1x GrovePi+ Guidebook
10x Cables
1x Grove - UItrasonic Ranger
1x Grove - Green LED
The Pimoroni Explorer Starter Kit is an electronic adventure playground for physical computing based on the RP2350 chip. It includes a 2.8-inch LCD screen, a speaker, a mini breadboard and much more. It's ideal for tinkering, experiments, and building small prototypes.
Features
Mini breadboard for wiring up components
Servo headers
Analog inputs
Built-in speaker
Plenty of general purpose inputs/outputs
Connectors for attaching crocodile leads
Qw/ST connectors for attaching I²C breakouts
Specifications
Powered by RP2350B (Dual Arm Cortex-M33 running at up to 150 MHz with 520 KB of SRAM)
16 MB of QSPI flash supporting XiP
2.8" IPS LCD screen (320 x 240 pixels)
Driver IC: ST7789V
Luminance: 250 cd/m²
Active area: 43.2 x 57.5 mm
USB-C connector for programming and power
Mini breadboard
Piezo speaker
6x user-controllable switches
Reset and boot buttons
Easy access GPIO headers (6x GPIOs and 3x ADCs, plus 3.3 V power and grounds)
6x Crocodile clip terminals (3x ADCs, plus 3.3 V power and grounds)
4x 3-pin servo outputs
2x Qw/ST (Qwiic/STEMMA QT) connector
2-pin JST-PH connector for adding a battery
Lanyard slot!
Includes 2x desktop stand feet
Fully-assembled (no soldering required)
Programmable with C/C++ or MicroPython
Included
1x Pimoroni Explorer
1x Multi-Sensor Stick – a fancy new all-in-one super sensor suite for environmental, light and movement sensing
Selection of different colored LEDs to get blinky with (including red, yellow, green, blue, white and RGB)
1x Potentiometer (for analog amusements)
3x 12 mm switches with different coloured caps
2x Continuous rotation servos
2x 60 mm wheels for attaching to your servos
1x AAA battery holder (batteries not included)
1x Velcro to stick the battery holder to the back of Explorer
20x Pin to pin and 20x pin to socket jumper wires for making connections on your breadboard
1x Qw/ST cable to plug in the Multi-Sensor Stick
1x Silicon USB-C cable
Downloads
GitHub
Schematic
The Milk-V Duo 256M is an ultra-compact embedded development platform based on the SG2002 chip. It can run Linux and RTOS, providing a reliable, low-cost, and high-performance platform for professionals, industrial ODMs, AIoT enthusiasts, DIY hobbyists, and creators.
This board is an upgraded version of Duo with a memory boost to 256M, catering to applications demanding larger memory capacities. The SG2002 elevates computational power to 1.0 TOPS @ INT8. It enables seamless switching between RISC-V/ARM architectures and supports simultaneous operation of dual systems. Additionally, it includes an array of rich GPIO interfaces such as SPI, UART, suitable for a wide range of hardware development in edge intelligent monitoring, including IP cameras, smart peephole locks, visual doorbells, and more.
SG2002 is a high-performance, low-power chip designed for various product fields such as edge intelligent surveillance IP cameras, smart door locks, visual doorbells, and home intelligence. It integrates H.264 video compression and decoding, H.265 video compression encoding, and ISP capabilities. It supports multiple image enhancement and correction algorithms such as HDR wide dynamic range, 3D noise reduction, defogging, and lens distortion correction, providing customers with professional-grade video image quality.
The chip also incorporates a self-developed TPU, delivering 1.0 TOPS of computing power under 8-bit integer operations. The specially designed TPU scheduling engine efficiently provides high-bandwidth data flow for all tensor processing unit cores. Additionally, it offers users a powerful deep learning model compiler and software SDK development kit. Leading deep learning frameworks like Caffe and Tensorflow can be easily ported to its platform. Furthermore, it includes security boot, secure updates, and encryption, providing a series of security solutions from development, mass production, to product applications.
The chip integrates an 8-bit MCU subsystem, replacing the typical external MCU to achieve cost-saving and power efficiency goals.
Specifications
SoC
SG2002
RISC-V CPU
C906 @ 1 Ghz + C906 @ 700 MHz
Arm CPU
1x Cortex-A53 @ 1 GHz
MCU
8051 @ 6 KB SRAM
Memory
256 MB SIP DRAM
TPU
1.0 TOPS @ INT8
Storage
1x microSD connector or 1x SD NAND on board
USB
1x USB-C for power and data, USB Pads available
CSI
1x 16P FPC connector (MIPI CSI 2-lane)
Sensor Support
5 M @ 30 fps
Ethernet
100 Mbps Ethernet with PHY
Audio
Via GPIO Pads
GPIO
Up to 26x GPIO Pads
Power
5 V/1 A
OS Support
Linux, RTOS
Dimensions
21 x 51 mm
Downloads
Documentation
GitHub
The CubeCell series is designed primarily for LoRa/LoRaWAN node applications.
Built on the ASR605x platform (ASR6501, ASR6502), these chips integrate the PSoC 4000 series MCU (ARM Cortex-M0+ Core) with the SX1262 module. The CubeCell series offers seamless Arduino compatibility, stable LoRaWAN protocol operation, and straightforward connectivity with lithium batteries and solar panels.
The HTCC-AB02S is a developer-friendly board with an integrated AIR530Z GPS module, ideal for quickly testing and validating communication solutions.
Features
Arduino compatible
Based on ASR605x (ASR6501, ASR6502), those chips are already integrated the PSoC 4000 series MCU (ARM Cortex M0+ Core) and SX1262
LoRaWAN 1.0.2 support
Ultra low power design, 21 uA in deep sleep
Onboard SH1.25-2 battery interface, integrated lithium battery management system (charge and discharge management, overcharge protection, battery power detection, USB/battery power automatic switching)
Good impendence matching and long communication distance
Onboard solar energy management system, can directly connect with a 5.5~7 V solar panel
Micro USB interface with complete ESD protection, short circuit protection, RF shielding, and other protection measures
Integrated CP2102 USB to serial port chip, convenient for program downloading, debugging information printing
Onboard 0.96-inch 128x64 dot matrix OLED display, which can be used to display debugging information, battery power, and other information
Using Air530 GPS module with GPS/Beidou Dual-mode position system support
Specifications
Main Chip
ASR6502 (48 MHz ARM Cortex-M0+ MCU)
LoRa Chipset
SX1262
Frequency
863~870 MHz
Max. TX Power
22 ±1 dBm
Max. Receiving Sensitivity
−135 dBm
Hardware Resource
2x UART1x SPI2x I²C1x SWD3x 12-bit ADC input8-channel DMA engine16x GPIO
Memory
128 Kb FLASH16 Kb SRAM
Power consumption
Deep sleep 21 uA
Interfaces
1x Micro USB1x LoRa Antenna (IPEX)2x (15x 2.54 Pin header) + 3x (2x 2.54 Pin header)
Battery
3.7 V lithium battery (power supply and charging)
Solar Energy
VS pin can be connected to 5.5~7 V solar panel
USB to Serial Chip
CP2102
Display
0.96" OLED (128 x 64)
Operating temperature
−20~70°C
Dimensions
55.9 x 27.9 x 9.5 mm
Included
1x CubeCell HTCC-AB02S Development Board
1x Antenna
1x 2x SH1.25 battery connector
Downloads
Datasheet
Schematic
GPS module (Manual)
Quick start
GitHub
With this comprehensive complete set, you can now enter the fascinating world of electronics. In addition to an Oxocard Connect and a breadboard cartridge, it contains 96 electronic components with which you can build a variety of electronic circuits.
Features
Free and unlimited access to the nanopy.io editor with a variety of scripts that you can transfer to your Oxocard Connect at the touch of a button.
Electronics course with 15 experiments that show you step by step how to switch LEDs, connect a servo, generate acoustic signals with a piezo and much more.
Oxocard Connect
High quality microcontroller device with TFT screen, glass cover, joystick, USB-C, as well as revolutionary 16-pin cartridge slot.
The Oxocard Connect represents the next generation of small experimental computers. The universal cartridge slot allows ready-made or self-developed boards to be brought to life instantly by simply plugging them in. Each card comes with drivers and demo programs installed and automatically loaded and started when plugged in.
Breadboard Cartridge
With the Breadboard you can quickly plug in your own circuits. A plug-in board with 17 rows is available for this purpose. Connections: two analog inputs, five digital ports, I²C, SPI, GND/V3.3. access to the 5 V power source of the port. Red LEDs are attached to the digital pins. 5 V can also be injected to power the Oxocard Connect without USB.
Included
1x Oxocard Connect
1x Breadboard Cartridge
Electronic components
1x PIR-Sensor (Motion detector)
1x Thermistor 10 kΩ (Temperature sensor)
1x Photoresistor 10 kΩ (Light sensor)
1x Potentiometer
1x Mikroservo SG92R
1x Piezo (Acoustic signals)
3x LED (green, yellow, red)
2x Buttons
9x Resistances
75x Cables (angled) – various colors and lengths
The Voice Interaction Satellite Kit can extend the reach of your base station to each room in your house and enable you to interact with the hardware based on where you issue your commands! You can arrange multiple Satellite Kits throughout your home to add new functionality to Base kit or any other smart speaker, extending your voice control across several rooms.
The Voice Interaction Satellite Kit is powered by a Raspberry Pi Zero W and the ReSpeaker 2-Mics Pi HAT. Along with the kit comes a speaker, a Grove - Temperature Humidity Sensor (SHT31) sensor, a Grove Relay, and a pegboard to hang it on a wall or create a nifty stand.
Note
All Satellite Kits require a Base kit or Raspberry Pi in order to operate as intended.
Unlock a world of interactive learning with the Science Kit R3's robust hardware and software. With the Arduino Nano RP2040 Connect, Arduino Science Carrier R3, and an impressive array of sensors at your disposal, you'll have everything you need to embark on an exhilarating educational journey. Meanwhile, the Science Journal app effortlessly bridges the gap between theory and practice, facilitating real-time data collection, recording, and interpretation.
The kit elevates the learning experience by nurturing an enhanced understanding of complex physics concepts through engaging hands-on experimentation. It promotes scientific literacy and hones critical thinking skills by providing real-world application scenarios. With its intuitive content guide, both teachers and students can navigate through scientific explorations with ease.
Features
Hands-on experimental learning: perform physical experiments, transforming abstract physics concepts into tangible and interactive experiences.
Real-time data collection & analysis: With the integration of the Science Journal app, the kit allows students to collect, record, and interpret real-time data with mobile devices, strengthening their data literacy and scientific inquiry skills.
Teacher and student-friendly design: Equipped with a preloaded program, the kit requires no prior knowledge of coding or electronics. It also features Bluetooth connectivity for easy data transmission from the Arduino board to the students' mobile devices.
Comprehensive sensor ecosystem: The kit comes with multiple sensors, providing a wide range of data collection possibilities and keeping it adaptable to evolving educational needs.
Free guided courses – Explore Physics: Includes an intuitive courses guide that assists teachers and students in using the kit, presenting and analyzing data, and evaluating experimental outcomes. These courses also help students effectively communicate their scientific discoveries.
Comprehensive teaching support: With its intuitive guide, the Arduino Science Kit R3 eases the instructional process for teachers. It not only instructs on kit usage, but also assists in data presentation, analysis, and evaluation, ensuring students communicate their scientific discoveries effectively.
Specifications
Hardware
Arduino Nano RP2040 Connect
Arduino Science Carrier R3
Embedded sensors:
Air quality, temperature, humidity & pressure
IMU: 6-axis linear accelerometer, gyroscope, and magnetometer
Proximity, ambient light, light color
Voltage or electric potential difference
Electrical current
Electrical resistance
Function generators to see and hear the effect of frequency, amplitude, and phase on a sound wave
Ambient sound intensity sensor
Ports
2x Grove analog inputs (for external temperature-probe sensor)
2x Grove I²C ports (for external distance & ping-echo sensor)
1x Battery JST connector
2x Output ports connected to lower power signal from function generators (future generation)
1x 3.3 V output port and Ground
2x speaker ports connected to function generators
Other
50 cm double-ended cable (blue): crocodile clips one end, banana plug the other
20 cm double-ended cable (black): crocodile clips one end, banana plug the other
20 cm double-ended cable (red): crocodile clips one end, banana plug the other
VELCRO strips
Silicon stands
External temperature probe sensor
Ultrasonic distance sensor
Grove cable 4-pin housing with lock x2 (L=200 mm)
USB-C Cable
50 cm double-ended cable (yellow): crocodile clips one end, banana plug the other
2x Speakers
Cable for battery holder with JST connector
Battery holder for four 1V5 AA batteries
MDP-M01 is a display control module equipped with a 2.8-inch TFT display screen, the screen can be turned 90 degrees, which is convenient for users to view data and waveform. MDP-M01 can realize online display and control with MDP-P906 mini digital power supply modules and other modules of MDP system through 2.4 GHz wireless communication, and can control up to 6 sub-modules at the same time.
Specifications
Screen size
2.8' TFT
Screen resolution
240 x 320
Power
Micro USB power input, or taking power from sub-module via dedicated power cable
Input
DC 5 V/0.3 A
Other functions
Can control up to 6 sub-modulesUpgrade formware through Micro USB
Dimensions
107 x 66 x 13.6 mm
Weight
133 g
Included
1x MDP-M01 Smart Digital Monitor
1x Cable (2.5 mm jack to Micro USB)
Downloads
User Manual v3.4
Firmware v1.32
The Portenta C33 is a powerful System-on-Module designed for low-cost Internet of Things (IoT) applications. Based on the R7FA6M5BH2CBG microcontroller from Renesas, this board shares the same form factor as the Portenta H7 and it is backward compatible with it, making it fully compatible with all Portenta family shields and carriers through its high-density connectors.
As a low-cost device, the Portenta C33 is an excellent choice for developers looking to create IoT devices and applications on a budget. Whether you're building a smart home device or a connected industrial sensor, the Portenta C33 provides the processing power and connectivity options you need to get the job done.
Quickly deploying AI-powered projects becomes quick and easy with Portenta C33, by leveraging a vast array of ready-to-use software libraries and Arduino sketches available, as well as widgets that display data in real time on Arduino IoT Cloud-based dashboards.
Features
Ideal for low-cost IoT applications with Wi-Fi/Bluetooth LE connectivity
Supports MicroPython and other high-level programming languages
Offers industrial-grade security at the hardware level and secure OTA firmware updates
Leverages ready-to-use software libraries and Arduino sketches
Perfect to monitor and display real-time data on Arduino IoT Cloud widget-based dashboards
Compatible with Arduino Portenta and MKR families
Features castellated pins for automatic assembly lines
Cost Effective Performance
Reliable, secure and with computational power worthy of its range, Portenta C33 was designed to provide big and small companies in every field with the opportunity to access IoT and benefit from higher efficiency levels and automation.
Applications
Portenta C33 brings more applications than ever within users’ reach, from enabling quick plug-and-play prototyping to providing a cost-effective solution for industrial-scale projects.
Industrial IoT gateway
Machine monitoring to track OEE/OPE
Inline quality control and assurance
Energy consumption monitoring
Appliances control system
Ready-to-use IoT prototyping solution
Specifications
Microcontroller
Renesas R7FA6M5BH2CBG ARM Cortex-M33:
ARM Cortex-M33 core up to 200 MHz
512 kB onboard SRAM
2 MB onboard Flash
Arm TrustZone
Secure Crypto Engine 9
External Memories
16 MB QSPI Flash
USB-C
USB-C High Speed
Connectivity
100 MB Ethernet interface (PHY)
Wi-Fi
Bluetooth Low Energy
Interfaces
CAN
SD Card
ADC
GPIO
SPI
I²S
I²C
JTAG/SWD
Security
NXP SE050C2 Secure Element
Operating Temperatures
-40 to +85°C (-40 to 185°F)
Dimensions
66,04 x 25,40 mm
Downloads
Datasheet
Schematics
This is a high-performance cooling solution designed to effectively dissipate heat and ensure optimal operating temperatures for the Raspberry Pi. It is an essential accessory for users who want to enhance the performance and longevity of their Raspberry Pi device.
The compact design of the Water cooling kit for Raspberry Pi 5 allows it to be seamlessly installed on the top and bottom of the Raspberry Pi 5, ensuring efficient heat transfer and perfectly protecting the bottom of the Raspberry Pi. Its simple installation process eliminates the need for complex wiring or additional tools, making it friendly to both beginners and experienced Raspberry Pi enthusiasts.
With its powerful cooling performance, the water cooling kit for Raspberry Pi 5 for effectively dissipates heat generated by the Raspberry Pi during intensive tasks or prolonged usage. This helps prevent overheating and ensures stable performance. Efficient water-cooled cooling will allow you to connect multiple Raspberry Pi boards to a set of cooling devices. When using Raspberry Pi in a cluster, you can use a set of water-cooled devices to effectively cool multiple Raspberry Pi boards.
Features
Made for Raspberry Pi: Specially designed for Raspberry Pi 5, 1:1 mold opening, covering all heat sources, including CPU, Wi-Fi, power chip, and eMMC.
Cooling Performance: Effectively dissipates the heat generated by the Raspberry Pi, ensuring optimal operating temperatures and preventing overheating.
Easy to Use: The integrated design of the water pump and cooling fan is convenient for users to install.
RGB Color Lighting: RGB-colored lights are installed at the fan and water pump locations.
Included
1x Water cooling kit
1x Water cooling radiator
1x Black heatsink
2x Silicone hose
1x 12 V/2 A power adapter (US)
4x Hexagonal screw M2.5x10
1x L-key hex wrench
The CS Mount Lens (3 MP, 6 mm) is designed for use with the Raspberry Pi HQ Camera Module, delivering sharp, detailed imaging for various applications.
The Arduino Pro Portenta Max Carrier transforms Portenta modules into single-board computers or reference designs that enable edge AI for high-performance industrial, building automation and robotics applications. Thanks to dedicated high-density connectors, it can be paired with Portenta X8 or H7, allowing you to easily prototype and deploy your industrial projects. This Arduino Pro carrier further augments Portenta connectivity options with Fieldbus, LoRa, Cat-M1 and NB-IoT.
Among the many available plug-and-play connectors there are Ethernet, USB-A, audio jacks, microSD, mini-PCIe, FD-CAN and Serial RS232/422/485.
Max Carrier can be powered via external supply (6-36 V) or battery via the onboard 18650 Li-ion battery connector with 3.7 V battery charger.
Features
Easily prototype industrial applications and minimize time to market
A powerful carrier exposing Portenta peripherals (e.g. CAN, RS232/422/485, USB, mPCIe)
Multiple connectivity options (Ethernet, LoRa, CAT-M1, NB-IoT)
MicroSD for data logging operations
Integrated audio jacks (line-in, line-out, mic-in)
Standalone when battery powered
Onboard JTAG debugger via micro-USB (with Portenta H7 only)
Specifications
Connectors
High-Density connectors compatible with Portenta products2x USB-A female connectors1x Gigabit Ethernet connector (RJ45)1x FD-Can on RJ111x mPCIe1x Serial RS232/422/485 on RJ12
Audio
3x audio jacks: stereo line-in/line-out, mic-inSpeaker connector
Memory
Micro SD
Wireless modules
Murata CMWX1ZZABZ-078 LoRaSARA-R412M-02B (Cat.M1/NB-IoT)
Operating temperatures
-40 °C to +85 °C (-40° F to 185 °F)
Debugging
Onboard JLink OB / Blackmagic probe
Power/battery
Power Jack for external supply (6-36 V)On-board 18650 Li-ion battery connector with battery charger (3.7 V)
Dimensions
101.6 x 101.6 mm (4.0 x 4.0')
Downloads
Datasheet
Schematics
Arduino MKR NB 1500 allows you to build your next smart project.
Ever wanted an automated house? Or a smart garden? Well, now it’s easy with the Arduino IoT Cloud compatible boards. It means: you can connect devices, visualize data, control and share your projects from anywhere in the world. Whether you’re a beginner or a pro, we have a wide range of plans to make sure you get the features you need.
Add Narrowband communication to your project with the MKR NB 1500. It's the perfect choice for devices in remote locations without an Internet connection, or in situations in which power isn't available like on-field deployments, remote metering systems, solar-powered devices, or other extreme scenarios.
The board's main processor is a low power ARM Cortex-M0 32-bit SAMD21, like in the other boards within the Arduino MKR family. The Narrowband connectivity is performed with a module from u-blox, the SARA-R410M-02B, a low power chipset operating in the de different bands of the IoT LTE cellular range. On top of those, secure communication is ensured through the Microchip ECC508 crypto chip. Besides that, the pcb includes a battery charger, and a connector for an external antenna.
This board is designed for global use, providing connectivity on LTE's Cat M1/NB1 bands 1, 2, 3, 4, 5, 8, 12, 13, 18, 19, 20, 25, 26, 28. Operators offering service in that part of the spectrum include: Vodafone, AT&T, T-Mobile USA, Telstra, and Verizon, among others.
Specifications
The Arduino MKR NB 1500 is based on the SAMD21 microcontroller.
Microcontroller
SAMD21 Cortex-M0+ 32-bit low power ARM MCU (datasheet)
Radio module
u-blox SARA-R410M-02B (datasheet summary)
Secure element
ATECC508 (datasheet)
Board power supply (USB/VIN)
5 V
Supported battery
Li-Po Single Cell, 3.7 V, 1500 mAh Minimum
Circuit operating voltage
3.3 V
Digital I/O pins
8
PWM pins
13 (0 .. 8, 10, 12, 18 / A3, 19 / A4)
UART
1
SPI
1
I²C
1
Analog input pins
7 (ADC 8/10/12 bit)
Analog output pins
1 (DAC 10 bit)
External interrupts
8 (0, 1, 4, 5, 6, 7, 8, 16 / A1, 17 / A2)
DC current per I/O pin
7 mA
Flash memory
256 KB (internal)
SRAM
32 KB
EEPROM
No
Clock speed
32.768 kHz (RTC), 48 MHz
LED_BUILTIN
6
USB
Full-speed USB device and embedded host
Antenna gain
2 dB
Carrier frequency
LTE bands 1, 2, 3, 4, 5, 8, 12, 13, 18, 19, 20, 25, 26, 28
Power class (radio)
LTE Cat M1 / NB1: Class 3 (23 dBm)
Data rate (LTE M1 halp-duplex)
UL 375 kbps / DL 300 kbps
Data rate (LTE NB1 full-duplex)
UL 62.5 kbps / DL 27.2 kbps
Working region
Multiregion
Device location
GNSS via modem
Power consumption (LTE M1)
min 100 mA / max 190 mA
Power consumption (LTE NB1)
min 60 mA / max 140 mA
SIM card
MicroSIM (not included with the board)
Dimensions
67.6 x 25 mm
Weight
32 g
Downloads
Eagle Files
Schematics
Pinout
This fiberglass outdoor antenna is optimized for receiving signals in the 868 MHz ISM band, supporting technologies such as Sigfox, LoRa, Mesh Networks, and Helium. The antenna consists of a half-wave dipole with 4.4 dBi gain, encapsulated inside a fiberglass radome with an aluminum mounting base.
Specifications
Frequency
868-870 MHz
Antenna type
Dipole 1/2 wave
Connector
N female
Installation type
Mast Diam 35-60 mm (mounting bracket included)
Gain
4.4 dBi
SWR
≤1.5
Type of Polarization
Vertical
Maximum power
10 W
Impedance
50 Ohms
Dimensions
52.5 cm
Tube diameter
26 mm
Base antenna
32 mm
Operating temperature
−30°C to +60°C
Included
ISM Band Antenna (868 Mhz)
Mast bracket (for installation on a 35 to 60 mm diameter mast)
The MLX90640 SparkFun IR Array Breakout features a 32×24 array of thermopile sensors generating, in essence, a low resolution thermal imaging camera. With this breakout you can observe surface temperatures from a decent distance away with an accuracy of ±1.5°C (best case). This board communicates via I²C using the Qwiic system developed by Sparkfun, which makes it easier to operate the breakout. However, there are still 0.1'-spaced pins in case you favour using a breadboard.
The SparkFun Qwiic connect system is an ecosystem of I²C sensors, actuators, shields and cables that make prototyping faster and helps you avoid errors. All Qwiic-enabled boards use a common 1 mm pitch, 4-pin JST connector. This reduces the amount of required PCB space, and polarized connections help you connect everything correctly.
This specific IR Array Breakout provides a 110°×75° field of view with a temperature measurement range of -40~300°C. The MLX90640 IR Array has pull up resistors attached to the I²C bus; both can be removed by cutting the traces on the corresponding jumpers on the back of the board. Please be aware that the MLX90640 requires complex calculations by the host platform so a regular Arduino Uno (or equivalent) doesn't have enough RAM or flash to complete the complex computations required to turn the raw pixel data into temperature data. You will need a microcontroller with 20,000 bytes or more of RAM.
Designed with cutting-edge technology, this shield brings the power of Ultra High Frequency (UHF) RFID to your fingertips.
With the Ardi UHF Shield, you can effortlessly read up to an impressive 50 tags per second, allowing for fast and efficient data collection. The shield features an onboard UHF antenna, ensuring reliable and accurate tag detection even in challenging environments.
Equipped with a high-performance 0.91" OLED display, the Ardi UHF Shield provides clear and concise visual feedback, making it easy to monitor and interact with the RFID readings. Whether you're tracking inventory, managing access control, or implementing a smart attendance system, this shield has you covered.
With a remarkable 1-meter reading distance, the Ardi UHF Shield offers an extended range for capturing RFID data. Say goodbye to the limitations of proximity-based RFID systems and embrace the flexibility and convenience of a wider reading range.
The shield provides read-write capabilities, allowing you to not only retrieve information from RFID tags but also update or modify data as needed. This versatility opens up a world of possibilities for advanced applications and custom solutions.
Features
Onboard High-performance UHF RFID reader module
24 hours x 365 days’ work normally
0.91” OLED display for visual interaction with shield
Multi-tone Buzzer onboard for Audio alerts
Shield compatible with both 3.3 V and 5 V MCU
Mounts directly onto ArdiPi, Ardi32 or other Arduino compatible boards
Specifications
OLED resolution 128x32 pixels
I²C Interface for OLED
UHF Frequency Range (EU/UK): 865.1-867.9 MHz
UHF Module Type: Read/Write
Protocols Supported: EPCglobal UHF Class 1 Gen 2 / ISO 18000-6C
Reading Distance: 1 meters
Can identify over 50 tags simultaneously
Communication interface: TTL UART Interface for UHF
Communication baud rate: 115200 bps (default and recommend) – 38400 bps
Operation current: 180 mA @ 3.5 V (26 dBm Output, 25°C), 110 mA @ 3.5 V (18 dBm Output, 25°C)
Working humidity <95% (+25°C)
Heat-dissipating method Air cooling(no need out install cooling fin)
Tags storage capacity: 200 pcs tags @ 96 bit EPC
Output power: 18-26 dBm
Output power accuracy: +/-1 dB
Tags RSSI support
The Nicla Sense ME is a tiny, low-power tool that sets a new standard for intelligent sensing solutions. With the simplicity of integration and scalability of the Arduino ecosystem, the board combines four state-of-the-art sensors from Bosch Sensortec:
BHI260AP motion sensor system with integrated AI
BMM150 magnetometer
BMP390 pressure sensor
BME688 4-in-1 gas sensor with AI and integrated high-linearity, as well as high-accuracy pressure, humidity and temperature sensors.
The Arduino Nicla Sense ME is the smallest Arduino form factor yet, with a range of industrial grade sensors packed into a tiny footprint. Measure process parameters such as temperature, humidity and movement. Featuring a 9-axis inertial measurement unit and the possibility for Bluetooth Low Energy connectivity, it can help you to create your next Bluetooth Low Energy enabled project. Make your own industrial grade wireless sensing network with the onboard BHI260AP, BMP390, BMM150 and BME688 Bosch sensors.
Features
Tiny size, packed with features
Low power consumption
Add sensing capabilities to existing projects
When battery-powered, becomes a complete standalone board
Powerful processor, capable of hosting intelligence on the Edge
Measures motion and environmental parameters
Robust hardware including industrial-grade sensors with embedded AI
BLE connectivity maximizes compatibility with professional and consumer equipment
24/7 always-on sensor data processing at ultra-low power consumption
Specifications
BHI260AP – Self-learning AI smart sensor with integrated accelerometer and gyroscope
BMP390 – Digital pressure sensor
BMM150 – Geomagnetic sensor
BME688 – Digital low power gas, pressure, temperature & humidity sensor with AI
Microcontroller
64 MHz ARM Cortex-M4 (nRF52832)
Sensors
I/O
Castellated pins with the following features:
1x I²C bus (with ext. ESLOV connector)
1x Serial port
1x SPI
2x ADC, programmable I/O voltage from 1.8-3.3 V
Connectivity
Bluetooth 4.2
Power
Micro USB (USB-B), Pin Header, 3.7 V Li-po battery with Integrated battery charger
Memory
512 KB Flash / 64 KB RAM
2 MB SPI Flash for storage
2 MB QSPI dedicated for BHI260AP
Interface
USB interface with debug functionality
Dimensions
22.86 x 22.86 mm
Weight
2 g
Downloads
Datasheet
This is an add-on kit for the Seeed Studio Grove Beginner Kit for Arduino.
Applications
Suitable for Arduino beginners
Suitable for infrared control and motion detect
Suitable for getting started with open-source hardware and Arduino coding
Included
1x Grove Water Atomization
1x Grove Mini Fan
1x Grove Servo
1x Grove Ultrasonic Distance Sensor
1x Grove Infrared Receiver
1x Grove Mini PIR Motion Sensor
1x Grove Green Wrapper
1x Grove Blue Wrapper
5x Grove Cable
1x Infrared Remote Control Key
1x Ultrasonic Sensor Bracket Set
1x Motor Bracket Set
1x Servo Base
TapNLink modules provide wireless interfaces for linking electronic systems to mobile devices and the Cloud. TapNLink connects directly to the target system's microcontroller. It integrates into and is powered by the target system. All TapNLink products are easily configured to control access by different types of users to data in the target system.
TapNLink facilitates rapid creation of Human Machine Interfaces (HMI) that run on Android, iOS and Windows mobiles. HMI apps are easily customized for different users and can be deployed and updated to keep pace with evolving system requirements and user needs.
TapNLink Wi-Fi modules can also be configured to connect the target system permanently to a wireless network and the Cloud. This enables permanent logging of target system data and alarms.
Features
Wireless Channels
Wi-Fi 802.11b/g/n
Bluetooth Low Energy (BLE 4.2)
Near Field Communication (NFC) Type5 tag (ISO/IEC 15693)
Supported Target Connections: Connects on 2 GPIO of the target microcontroller and supports:
Serial interface with Software Secure Serial Port (S3P) protocol
Serial interface with ARM SWD debug protocol.
UART with Modbus protocol
Mobile Platform Support
HTML5 web apps (Android, iOS)
API for Cordova (Android, iOS, Windows 10)
Java (Android, iOS native)
Auto-app generator for Android and iOS mobiles
Security
Configurable access profiles
Configurable, encrypted passwords
AES-128/256 module-level data encryption
Configurable secure pairing with NFC
Dimensions: 38 mm x 28 mm x 3 mm
Electrical Characteristics
Input voltage: 2.3V to 3.6 V
Low power consumption:
Standby: 100 µA
NFC Tx/Rx: 7 mA
Wi-Fi Rx: 110 mA
Wi-Fi Tx : 280 mA (802.11b)
Temperature Range: -20°C ~ +55°C
Compliance
CE (Europe), FCC (USA), IC (Canada)
REACH
RoHS
WEEE
Ordering Information
Base Part Number: TnL-FIW103
MOQ: 20 modules
TapNLink modules pre-qualified, pre-programmed and ready to configure.
IoTize Studio configuration and testing software
Software for HMI on mobile devices (iOS, Android, Windows 10)
IoTize Cloud MQTT infrastructure (open source)
For more information, check out the datasheet here.
