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The board contains everything needed to support the microcontroller; simply connect it to a computer with a micro-USB cable or power it with an AC-to-DC adapter or battery to get started. The Due is compatible with all Arduino shields that work at 3.3V and are compliant with the 1.0 Arduino pinout. The Due follows the 1.0 pinout: TWI: SDA and SCL pins that are near to the AREF pin. IOREF: allows an attached shield with the proper configuration to adapt to the voltage provided by the board. This enables shield compatibility with a 3.3V board like the Due and AVR-based boards which operate at 5V. An unconnected pin, reserved for future use. Operating Voltage 3.3 V Input Voltage 7 V - 12 V Digital I/O 54 Analog Input Pins 12 Analog Output Pins 2 (DAC) Total DC Output Current on all I/O Lines 130 mA DC Current per I/O Pin 20 mA DC Current for 3.3 V Pin 800 mA DC Current for 5 V Pin 800 mA Flash Memory 512 KB all available for the user applications SRAM 96 KB Clock Speed 84 MHz Length 101.52 mm Width 53.3 mm Weight 36 g Please note: Unlike most Arduino boards, the Arduino Due board runs at 3.3V. The maximum voltage that the I/O pins can tolerate is 3.3V. Applying voltages higher than 3.3V to any I/O pin could damage the board.

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The board's main processor is a low-power Arm® Cortex®-M0 32-bit SAMD21. The WiFi and Bluetooth® connectivity is performed with a module from u-blox, the NINA-W10, a low-power chipset operating in the 2.4GHz range. On top of that, secure communication is ensured through the Microchip® ECC608 crypto chip. Besides that, you can find a 6 axis IMU, which makes this board perfect for simple vibration alarm systems, pedometers, the relative positioning of robots, etc. WiFi and Arduino IoT Cloud You can get your board to connect to any kind of existing WiFi network, or use it to create your own Arduino Access Point. The specific set of examples we provide for the Nano 33 IoT can be consulted at the WiFiNINA library reference page. It is also possible to connect your board to different Cloud services, Arduino's own among others. Here are some examples of how to get the Arduino boards to connect to: Arduino's own IoT Cloud: Arduino's IoT Cloud is a simple and fast way to ensure secure communication for all of your connected Things. Check it out here. Blynk: a simple project from our community connecting to Blynk to operate your board from a phone with little code. IFTTT: see an in-depth case of building a smart plug connected to IFTTT. AWS IoT Core: we made this example on how to connect to Amazon Web Services. Azure: visit this GitHub repository explaining how to connect a temperature sensor to Azure's Cloud. Firebase: you want to connect to Google's Firebase, this Arduino library will show you how. Microcontroller SAMD21 Cortex®-M0+ 32bit low power ARM MCU Radio Module u-blox NINA-W102 Secure Element ATECC608A Operating Voltage 3.3 V Input Voltage 21 V Digital I/O Pins 14 PWM Pins 11 DC Current per I/O Pin 7 mA Analog Input Pins 8 Analog Output Pins 1 External Interrupts all digital pins UART 1 SPI 1 I2C 1 Flash Memory 256 KB SRAM 32 KB EEPROM none Clock Speed 48 MHz LED_Builtin 13 USB Native in the SAMD21 Processor IMU LSM6DS3 Length 45 mm Width 18 mm Weight 5 g

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Quickly and easily get started with learning electronics using the Arduino Uno Starter Kit, which have a universal appeal to fans at home, businesses, and schools alike. No prior experience is required, as the kits introduce both coding and electronics through fun, engaging, and hands-on projects. You can use the starter kit to teach students about current, voltage, and digital logic as well as the fundamentals of programming. There’s an introduction to sensors and actuators and how to understand both digital and analog signals. Within all this, you’ll be teaching students how to think critically, learn collaboratively, and solve problems. Projects Book GET TO KNOW YOUR TOOLS an introduction to the basics SPACESHIP INTERFACE design the control panel for your starship LOVE-O-METER measure how hot-blooded you are COLOR MIXING LAMP produce any colour with a lamp that uses light as an input MOOD CUE clue people into how you're doing LIGHT THEREMIN create a musical instrument you play by waving your hands KEYBOARD INSTRUMENT play music and make some noise with this keyboard DIGITAL HOURGLASS a light-up hourglass that can stop you from working too much MOTORIZED PINWHEEL a coloured wheel that will make your head spin ZOETROPE create a mechanical animation you can play forward or reverse CRYSTAL BALL a mystical tour to answer all your tough questions KNOCK LOCK tap out the secret code to open the door TOUCHY-FEEL LAMP a lamp that responds to your touch TWEAK THE ARDUINO LOGO control your personal computer from your Arduino HACKING BUTTONS create a master control for all your devices! Included 1 Projects Book (170 pages) 1 Arduino Uno 1 USB cable 1 Breadboard 400 points 70 Solid core jumper wires 1 Easy-to-assemble wooden base 1 9 V battery snap 1 Stranded jumper wires (black) 1 Stranded jumper wires (red) 6 Phototransistor 3 Potentiometer 10 kΩ 10 Pushbuttons 1 Temperature sensor [TMP36] 1 Tilt sensor 1 alphanumeric LCD (16x2 characters) 1 LED (bright white) 1 LED (RGB) 8 LEDs (red) 8 LEDs (green) 8 LEDs (yellow) 3 LEDs (blue) 1 Small DC motor 6/9 V 1 Small servo motor 1 Piezo capsule 1 H-bridge motor driver 1 Optocouplers 2 Mosfet transistors 3 Capacitors 100 uF 5 Diodes 3 Transparent gels 1 Male pins strip (40x1) 20 Resistors 220 Ω 5 Resistors 560 Ω 5 Resistors 1 kΩ 5 Resistors 4.7 kΩ 20 Resistors 10 kΩ 5 Resistors 1 MΩ 5 Resistors 10 MΩ

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Ever wanted an automated house? Or a smart garden? The Arduino IoT Cloud compatible board Nicla Vision allows you to build your next smart project. You can connect devices, visualize data, control and share your projects from anywhere in the world. Nicla Vision combines a powerful STM32H747AII6 Dual ARM Cortex M7/M4 IC processor with a 2 MP color camera that supports TinyML, as well as a smart 6-axis motion sensor, integrated microphone and distance sensor. You can easily include it into any project because it’s designed to be compatible with all Arduino Portenta and MKR products, fully integrates with OpenMV, supports MicroPython and also offers both WiFi and Bluetooth Low Energy connectivity. It’s so compact – with its 22.86 x 22.86 mm form factor – it can physically fit into most scenarios, and requires so little energy it can be powered by battery for standalone applications. All of this makes Nicla Vision the ideal solution to develop or prototype with on-device image processing and machine vision at the edge, for asset tracking, object recognition, predictive maintenance and more – easier and faster than ever. Train it to spot details, so you can focus on the big picture. Automate anything Check every product is labeled before it leaves the production line; unlock doors only for authorized personnel, and only if they are wearing PPE correctly; use AI to train Nicla Vision to regularly check analog meters and beam readings to the Cloud; teach it to recognize thirsty crops and turn the irrigation on when needed.Anytime you need to act or make a decision depending on what you see, let Nicla Vision watch, decide and act for you. Feel seen Interact with kiosks with simple gestures, create immersive experiences, work with cobots at your side. Nicla Vision allows computers and smart devices to see you, recognize you, understand your movements and make your life easier, safer, more efficient, better. Keep an eye out Let Nicla Vision be your eyes: detecting animals on the other side of the farm, letting you answer your doorbell from the beach, constantly checking on the vibrations or wear of your industrial machinery. It’s your always-on, always precise lookout, anywhere you need it to be. Downloads Schematics Datasheet

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Learn the basics of electronics by assembling manually your Arduino Uno, become familiar with soldering by mounting every single component, and then unleash your creativity with the only kit that becomes a synth! The Arduino Make-Your-Uno kit is really the best way to learn how to solder. And when you are done, the packaging allows you to build a synth and make your music. A kit with all the components to build your very own Arduino Uno and audio synthesizer shield. The Make-Your-Uno kit comes with a complete set of instructions in a dedicated content platform. This includes video material, a 3D interactive viewer for following detailed instructions, and how to program your board once it is finished. This kit contains: Arduino Make-Your-Uno 1x Make-Your-Uno PCB 1x USB C Serial adapter Board 7x Resistors 1k Ohm 2x Resistors 10k Ohm 2x Resistors 1M Ohm 1x Diode (1N4007) 1x 16 MHz Crystal 4x Yellow LEDs 1x Green LED 1x Push-Button 1x MOSFET 1x LDO (3.3 V) 1x LDO (5 V) 3x Ceramic capacitors (22pF) 3x Electrolytic capacitors (47uF) 7x Polyester capacitors (100nF) 1x Socket for ATMega 328p 2x I/O Connectors 1x Connector header 6 pins 1x Barrel jack connector 1x ATmega 328p Microcontroller Arduino Audio Synth 1x Audio Synth PCB 1x Resistor 100k Ohm 1x Resistor 10 Ohm 1x Audio amplifier (LM386) 1x Ceramic capacitors (47nF) 1x Electrolytic capacitors (47uF) 1x Electrolytic capacitors (220uF) 1x Polyester capacitor (100nF) 4x connectors pin header 6x potentiometer 10k Ohm with plastic knobs Spare parts 2x Electrolytic capacitors (47uF) 2x Polyester capacitor (100nF) 2x Ceramic capacitors (22pF) 1x Push-Button 1x Yellow LEDs 1x Green LED Mechanical parts 5x Spacers 12 mm 11x Spacers 6 mm 5x screw nuts 2x screws 12 mm

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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

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Portenta Breakout board is designed to help hardware engineers and makers to prototype and help test devices connections and capacity within the Portenta family boards (e.g. the Portenta H7). It makes all high-density connectors’ signals individually accessible, making it quick and easy to connect and test external hardware components and devices as normally needed during development in the lab. Features PowerON Button Boot mode DIP switch Connectors USB-A RJ45 up to 1Gb/s Micro-SD Card MIPI-20T-JTAG with Trace-Capability. Power CR2032 RTC-Lithium battery backup External power terminal block I/O Break out all Portenta High Density connector signals Male/female HD connectors allow interposing breakout between Portenta and shield to debug signals Compatibility Standard Portenta High Density connector pinout Specifications USB Port USB-A Ethernet RJ45 up to 1 Gb/s Memory slot Micro SD card Debug MIPI-20T-JTAG with trace capability Connectors HD Male/Female RTC power battery CR2032 Dimensions 164 x 72 mm Weight 69 g Downloads Datasheet Schematics Pinout

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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

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Data Capture: Map the environment around the carrier using the integrated temperature, humidity, and pressure sensors and collect data about movement using the 6 axis IMU and light, gesture, and proximity sensors. Easily add more external sensors to capture more data from more sources via the on-board Grove connectors (x3). Data Storage: Capture and store all the data locally on an SD card, or connect to the Arduino IoT Cloud for real-time data capture, storage, and visualization. Data Visualisation: Locally view real-time sensor readings on the built-in OLED Color Display and create visual or sound prompts using the embedded LEDs and buzzer. Total Control: Directly control small-voltage electronic appliances using the onboard relays and the five tactile buttons, with the integrated display providing a handy on-device interface for immediate control.

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The best way to start exploring the world of connected devices using the Arduino MKR WiFi 1010. The MKR IoT bundle contains all you need to build your first connected devices. Follow the 5 step by step tutorials we have prepared for you and combining the electronic components included in the bundle, you’ll quickly learn how to build devices that connect to the Arduino IoT cloud. All you need to start with IoT This bundle is contains all the hardware and software required to build your first IoT devices with no extra fees. Build 5 IoT projects All the components needed to start your journey into building your own IoT projects. Learn about the Arduino IoT cloud Not only learn about electronic but also about the possibilities the Arduino IoT cloud can offer. Included 1x Arduino MKR1000 WiFi (with mounted headers) 6x Phototransistors 1x Tilt Sensor 1x Temperature sensor (TMP36) 3x Potentiometer 1x Piezo capsule 10x Pushbuttons 1x DC Motor 1x Small servo motor 1x Alphanumeric LCD (16x2 characters) 1x Optocouplers (4N35) 1x H-bridge motor driver (L293D) 2x Mosfet transistors (IRF520) 5x Capacitors 100uF 70x Solid core jumper wires 1x Micro USB cable 1x Breadboard 1x LED (bright white) 3x LEDs (blue) 1x LED (RGB) 8x LED 5 mm (red) 8x LED 5 mm (green) 8x LED 5 mm (yellow) 1x Male pins strip (4x1) 1x Stranded jumper wires (red) 1x Stranded jumper wires (black) 5x Diode 20x 220 Ω resistors 5x 560 Ω resistors 5x 1 KΩ resistors 5x 4.7 KΩ resistors 20x 10 KΩ resistors 5x 1 MΩ resistors 5x 10 MΩ resistors

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The Portenta Machine Control is a fully-centralized, low-power, industrial control unit able to drive equipment and machinery. It can be programmed using the Arduino framework or other embedded development platforms. Thanks to its computing power, the Portenta Machine Control enables a wide range of predictive maintenance and AI use cases. It enables the collection of real-time data from the factory floor and supports the remote control of equipment, even from the cloud, when desired. Features Shorter Time-To-Market Give new life to existing products Add connectivity for monitoring and control Tailor it to your need, each I/O pin can be configured Make equipment smarter to be ready for the AI revolution Provide security and robustness from the ground up Open new business model opportunity (e.g. servitization) Interact with your equipment with advanced HMI Modular Design for adaptation & upgrades The Portenta Machine Control allows companies to enable new business-as-a-service models by monitoring customer usage of equipment for predictive maintenance and providing valuable production data. The Portenta Machine Control enables industry standard soft-PLC control and is able to connect to a range of external sensors and actuators with isolated digital I/O, 4-20 mA compatible analog I/O, 3 configurable temperature channels, and a dedicated I²C connector. Multiple choices are available for network connectivity, including USB, Ethernet, and WiFi/Bluetooth Low Energy in addition to industry specific protocols such as RS485. All I/O are protected by resettable fuses and onboard power management has been engineered to ensure maximum reliability in harsh environments. The Portenta Machine Control core runs a Portenta H7 microcontroller board (included), a highly reliable design operating at industrial temperature ranges (-40 °C to +85 °C) with a dual-core architecture that doesn’t require any external cooling. The main processor offers the possibility of connecting external Human Machine Interfaces like displays, touch panels, keyboards, joysticks, and mice to enable on-site reconfiguration of state machines and direct manipulation of processes. The Portenta Machine Control’s design addresses a large variety of use scenarios. It is possible to configure a selection of the I/O pins via software. The Portenta Machine Control stands out as a powerful computer to unify and optimize production where one single type of hardware can serve all of your needs. Among other outstanding features are the following: Industrial performance leveraging the power of Portenta boards DIN bar compatible housing Push-in terminals for fast connection Compact device (170 x 90 x 50 mm) Reliable design, operating at industrial temperature rates (-40 °C to +85 °C) with a dual-core architecture that doesn’t require any external cooling Embedded RTC (Real Time Clock) to ensure perfect synchronization of processes Leverage the embedded connectivity without any external parts The Portenta Machine Control can be used in multiple industries, across a wide range of machine types, including: labelling machine, form & seal machine, cartoning machine, gluing machine, electric oven, industrial washer & dryers, mixers, etc. Add the Portenta Machine Control to your existing processes effortlessly and become the owner of your solutions in the market of machines. Specifications Processor STM32H747XI Dual Cortex-M7+M4 32-bit low power Arm MCU (Portenta H7) Input 8 digital 24 VDC 2 channels encoder readings 3 Analog for PT100/J/K temperature probes (3-wire cable with compensation) 3 Analog input (4-20 mA/ 0-10 V/NTC 10K) Output 8 digital 24 VDC up to 0.5 A (short circuit protection) 4 analog 0-10 V (up to 20 mA output per channel) Other I/O 12 programmable digital I/O (24 V logic) Commmunication protocols CAN-BUS Programmable Serial port 232/422/485 Connectivity Ethernet USB Programming Port Wi-Fi Bluetooth Low Energy Memory 16 MB onboard Flash memory 8 MB SD-RAM Dimensions 170 x 90 x 50 mm Weight 186 g Power 24 VDC +/- 20% Connector type Push-in terminals for fast connection Operating temperature -40 °C to +85 °C (-40 °F to 185 °F) Downloads Datasheet Schematics Pinout

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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 WiFi and Bluetooth connectivity is performed with a module from u-blox, the NINA-W10, a low-power chipset operating in the 2.4 GHz range. On top of that, secure communication is ensured through the Microchip ECC508 crypto chip. Besides that, you can find a battery charger, and an RGB LED on-board. Official Arduino WiFi Library You can get your board to connect to any kind of existing WiFi network, or use it to create your own Arduino Access Point. The specific set of examples we provide for the MKR WiFi 1010 can be consulted at the WiFiNINA library reference page. Compatible with other Cloud Services It is also possible to connect your board to different Cloud services, Arduino's own among others. Here are some examples of how to get the MKR WiFi 1010 to connect to: Blynk: a simple project from the Arduino community connecting to Blynk to operate your board from a phone with little code IFTTT: in-depth case of building a smart plug connected to IFTTT AWS IoT Core: Arduino made this example on how to connect to Amazon Web Services Azure: visit this GitHub repository explaining how to connect a temperature sensor to Azure's Cloud Firebase: you want to connect to Google's Firebase, this Arduino library will show you how Specifications Microcontroller SAMD21 Cortex-M0+ 32bit low power ARM MCU Radio Module u-blox NINA-W102 Power Supply 5 V Secure Element ATECC508 Supported Battery Li-Po Single Cell, 3.7 V, 1024 mAh Minimum Operating Voltage 3.3 V Digital I/O Pins 8 PWM Pins 13 UART 1 SPI 1 I2C 1 Analog Input Pins 7 Analog Output Pins 1 External Interrupts 10 Flash Memory 256 KB SRAM 32 KB EEPROM no Clock Speed 32.768 kHz, 48 MHz LED_Builtin 6 USB Full-Speed USB Device and embedded Host Length 61.5 mm Width 25 mm Weight 32 g

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Portenta H7 Lite 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. The Portenta H7 Lite is very similar to the Portenta H7, that simultaneously can run high level code along with real time tasks thanks to its two processors. It is, for example, possible to execute Arduino compiled code along with MicroPython one and have both cores to communicate with one another. However, the H7 Lite is a low-cost board with H7 functionalities that can be configured to specific use cases. Features Dual Core – Two best-in-class processors in one, running parallel tasks AI on the edge – So powerful it can run AI state machines Customization – The board is highly customizable in volumes High-level programming language support (Micropython) The Portenta H7 Lite offers twofold functionality: it can run either like any other embedded microcontroller board, or as the main processor of an embedded computer. For example, use the Portenta Vision Shield to transform your H7 Lite into an industrial camera capable of performing real-time machine learning algorithms on live video feeds. As the H7 Lite 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 carries out low-level operations like controlling a motor or acting as a user interface. Solutions High-end industrial machinery Laboratory equipment Computer vision PLCs Robotics controllers Mission-critical devices High-speed booting computation (ms) Two Parallel Cores The Portenta H7 Lite’s main processor is the STM32H747 dual core 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 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: simply upgrade your Portenta board to the one suiting your needs. 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, or to deliver power to OTG connected devices. Arduino IoT Cloud Use your Portenta board on Arduino’s IoT Cloud, a simple and fast way to ensure secure communication for all of your connected Things. Specifications Microcontroller STM32H747XI Dual Cortex-M7+M4 32-bit low power ARM MCU (datasheet) Secure element (default) Microchip ATECC608 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 Current consumption 2.95 μA in Standby mode (Backup SRAM OFF, RTC/LSE ON) 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, High / Full Speed, Power delivery Downloads Datasheet Schematics

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The Arduino MKR Zero is a development board for music makers! With an SD card holder and dedicated SPI interfaces (SPI1), you are able to play music files without extra hardware. The MKR Zero brings you the power of a Zero in the smaller format established by the MKR form factor. The MKR Zero board acts as a great educational tool for learning about 32-bit application development. It has an on-board SD connector with dedicated SPI interfaces (SPI1) that allows you to play with MUSIC files with no extra hardware! The board is powered by Atmel’s SAMD21 MCU, which features a 32-bit ARM Cortex M0+ core. The board contains everything needed to support the microcontroller; simply connect it to a computer with a micro-USB cable or power it by a LiPo battery. The battery voltage can also be monitored since a connection between the battery and the analog converter of the board exists. Specifications Microcontroller SAMD21 ARM Cortex-M0+ 32-bit low power Board power supply (USB/VIN) 5 V Supported battery Li-Po single cell, 3.7 V, 700 mAh minimum DC current for 3.3 V pin 600 mA DC current for 5 V pin 600 mA Circuit operating voltage 3.3 V Digital I/O pins 22 PWM pins 12 (0, 1, 2, 3, 4, 5, 6, 7, 8, 10, A3 - or 18 -, A4 -or 19) UART 1 SPI 1 I²C 1 Analog input pins 7 (ADC 8/10/12 bit) Analog output pins 1 (DAC 10 bit) External interrupts 10 (0, 1, 4, 5, 6, 7, 8, A1 -or 16-, A2 - or 17) DC current per I/O pin 7 mA Flash memory 256 KB Flash memory for bootloader 8 KB SRAM 32 KB EEPROM No Clock speed 32.768 kHz (RTC), 48 MHz LED_BUILTIN 32 Downloads Datasheet Eagle Files Schematics Fritzing Pinout

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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. Connect your sensors and actuators over long distances harnessing the power of the LoRa wireless protocol or throughout LoRaWAN networks. The Arduino MKR WAN 1310 board provides a practical and cost effective solution to add LoRa connectivity to projects requiring low power. This open source board can be connected to the Arduino IoT Cloud. Better and More Efficient The MKR WAN 1310, brings in a series of improvements when compared to its predecessor, the MKR WAN 1300. While still based on the Microchip SAMD21 low power processor, the Murata CMWX1ZZABZ LoRa module, and the MKR family’s characteristic crypto chip (the ECC508), the MKR WAN 1310 includes a new battery charger, a 2 MByte SPI Flash, and improved control of the board’s power consumption. Improved Battery Power The latest modifications have considerably improved the battery life on the MKR WAN 1310. When properly configured, the power consumption is now as low as 104 uA! It is also possible to use the USB port to supply power (5 V) to the board; run the board with or without batteries – the choice is yours. On-board Storage Data logging and other OTA (Over The Air) functions are now possible since the inclusion of the on board 2 MByte Flash. This new exciting feature will let you transfer configuration files from the infrastructure onto the board, create your own scripting commands, or simply store data locally to send it whenever the connectivity is best. Whilst the MKR WAN 1310’s crypto chip adds further security by storing credentials & certificates in the embedded secure element. These features make it the perfect IoT node and building block for low-power wide-area IoT devices. Specifications The Arduino MKR WAN 1310 is based on the SAMD21 microcontroller. Microcontroller SAMD21 Cortex-M0+ 32-bit low power ARM MCU (datasheet) Radio module CMWX1ZZABZ (datasheet) Board power supply (USB/VIN) 5 V Secure element ATECC508 (datasheet) Supported batteries Rechargeable Li-Ion, or Li-Po, 1024 mAh minimum capacity 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 CPU flash memory 256 KB (internal) QSPI flash memory 2 MByte (external) 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 (bundled pentaband antenna) Carrier frequency 433/868/915 MHz Dimensions 67.64 x 25 mm Weight 32 g Downloads Eagle Files Schematics Fritzing Pinout

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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 Microcontroller 64 MHz ARM Cortex-M4 (nRF52832) Sensors 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 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

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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

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The Arduino Nano 33 BLE Rev2 stands at the forefront of innovation, leveraging the advanced capabilities of the nRF52840 microcontroller. This 32-bit Arm Cortex-M4 CPU, operating at an impressive 64 MHz, empowers developers for a wide range of projects. The added compatibility with MicroPython enhances the board's flexibility, making it accessible to a broader community of developers. The standout feature of this development board is its Bluetooth Low Energy (Bluetooth LE) capability, enabling effortless communication with other Bluetooth LE-enabled devices. This opens up a realm of possibilities for creators, allowing them to seamlessly share data and integrate their projects with a wide array of connected technologies. Designed with versatility in mind, the Nano 33 BLE Rev2 is equipped with a built-in 9-axis Inertial Measurement Unit (IMU). This IMU is a game-changer, offering precise measurements of position, direction, and acceleration. Whether you're developing wearables or devices that demand real-time motion tracking, the onboard IMU ensures unparalleled accuracy and reliability. In essence, the Nano 33 BLE Rev2 strikes the perfect balance between size and features, making it the ultimate choice for crafting wearable devices seamlessly connected to your smartphone. Whether you're a seasoned developer or a hobbyist embarking on a new adventure in connected technology, this development board opens up a world of possibilities for innovation and creativity. Elevate your projects with the power and flexibility of the Nano 33 BLE Rev2. Specifications Microcontroller nRF52840 USB connector Micro USB Pins Built-in LED Pins 13 Digital I/O Pins 14 Analog Input Pins 8 PWM Pins All digital pins (4 at once) External interrupts All digital pins Connectivity Bluetooth u-blox NINA-B306 Sensors IMU BMI270 (3-axis accelerometer + 3-axis gyroscope) + BMM150 (3-axis Magnetometer) Communication UART RX/TX I²C A4 (SDA), A5 (SCL) SPI D11 (COPI), D12 (CIPO), D13 (SCK). Use any GPIO for Chip Select (CS) Power I/O Voltage 3.3 V Input Voltage (nominal) 5-18 V DC Current per I/O Pin 10 mA Clock Speed Processor nRF52840 64 MHz Memory nRF52840 256 KB SRAM, 1 MB flash Dimensions 18 x 45 mm Downloads Datasheet Schematics

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Arduino Alvik is a powerful and versatile robot specifically designed for programming and robotics education. Powered by the Arduino Nano ESP32, Arduino Alvik offers diverse learning paths through different programming languages, including MicroPython, Arduino C, and block-based coding, enabling different possibilities to explore robotics, IoT and AI. Arduino Alvik simplifies coding and complex robot projects, enabling users of all levels to immerse themselves in the exciting world of programming and robotics. It’s also a cross-discipline tool that bridges the gap between education and the future of robotics with CSTA and NGSS-Aligned free courses. This innovative and versatile robot makes learning and creating more accessible and fun than ever before. Features Powered by the versatile Nano ESP32, Alvik streamlines the learning curve in robotics with its comprehensive programming suite that includes MicroPython and Arduino language. Designed to accommodate users of all skill levels, Alvik soon plans to introduce block-based coding, further enhancing accessibility for younger students and providing an engaging entry point into robotics design. Alvik’s Time of Flight, RGB color and line-following array sensors, along with its 6-axis gyroscope and accelerometer, allow users to tackle a range of innovative, real-world projects. From an obstacle avoidance robot to a smart warehouse automation robot car, the possibilities are endless! Alvik comes equipped with LEGO Technic connectors, allowing users to personalize the robot and expand its capabilities. Additionally, it features M3 screw connectors for custom 3D or laser-cutter designs. The Servo, I²C Grove, and I²C Qwiic connectors allow users to expand Alvik’s potential and take robotics projects to a whole new level. Add motors for controlling movement and robotic arms, or integrate extra sensors for data collection and analysis. Specifiations Alvik main controller Arduino Nano ESP32: 8 MB of RAM u-blox NORA-W106 (ESP32-S3) Processor up to 240 MHz ROM 384 kB + SRAM 512 kB 16 MB External FLASH Alvik on-board Core STM32 Arm Cortex-M4 32 Bit Power supply Nano ESP32 USB-C rechargeable and replaceable 18650 Li-Ion battery (included) Programming language MicroPython, Arduino & block-based programming Connectivity Wi-Fi, Bluetooth LE Inputs Time of Flight Distance Sensor (up to 350 cm)RGB Color Sensor6-axis Gyroscope-Accelerometer3x Line follower Array7x Touchable Buttons Outputs 2x RGB LEDs6 V Motors (No load speed 96 rpm, No load current 70 mA) Extensions 4x LEGO Technic connectors8x M3 screw connectorsServo motorI²C GroveI²C Qwiic Downloads Datasheet Documentation

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Portenta HAT Carrier is a reliable and robust carrier that transforms Portenta X8 into an industrial single board computer compatible with Raspberry Pi HATs and cameras. It is ideal for multiple industrial applications such as building automation and machine monitoring.Compatible also with Portenta H7 and Portenta C33, Portenta HAT Carrier provides easy access to multiple peripherals – including CAN, Ethernet, microSD and USB – and further extends any Portenta application.It is great for prototyping and ready for scaling up, it extends the features found on a typical Raspberry Pi Model B. Debug quickly with dedicated JTAG pins and keeps heat manageable under intense workloads with a PWM fan connector. Control actuators or read analog sensors via the additional 16x analog I/Os. Add industrial machine vision solutions to any project by leveraging the onboard camera connector.Features Add Raspberry Pi HATs to your Portenta projects Quickly access CAN, USB, and Ethernet peripherals Leverage onboard MicroSD card to log data Enjoy simple debugging through the onboard JTAG pins Easily control actuators and read sensors via 16x analog I/Os Leveraging the onboard camera connector for machine vision Portenta takes you from prototype to high-performancePortenta HAT Carrier offers you a frictionless Linux prototyping experience and unlocks the ability for integrated real-time MCU solutions. Portenta HAT Carrier extends Portenta SOMs for faster, easier and more efficient testing for your ideas while also ensuring the capabilities and industrial-grade performances the Portenta range is known for.Extend the Raspberry Pi ecosystem for commercial applicationsCombine the ease of use, accessibility and incredible support from both the Arduino and Raspberry Pi communities for your next project with the carrier designed to combine and extend MPU and MCU applications for the development of advanced commercial solutions.Specifications Connectors High-density connectors compatible with Portenta products 1x USB-A female connector 1x Gigabit Ethernet connector (RJ45) 1x CAN FD with onboard transceiver 1x MIPI Camera connector 1x MicroSD card slot 1x PWM fan connector 40-pin header connector allowing compatibility with Raspberry Pi HATs 16-pin analog header connectors, including: 8x analog inputs 1x GPIO 1xUART without flow control 2x PWM pins 1x LICELL pin for Portenta's RTC power Interfaces CAN FD UART SAI ANALOG GPIO SPI I²C I²S PWM Debugging Onboard 10x pin 1.27 mm JTAG connector Power From onboard screw terminal block allowing: 7-32 V power supply, powering both the carrier and the connected Portenta 5 V power supply From USB-C on Portenta From 5 V on 40-pin header connector Dimensions 85 x 56 mm Downloads Datasheet Schematics

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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

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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

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The Portenta Cat. M1/NB IoT GNSS Shield allows you to enhance the connectivity features of your Portenta H7 applications. The shield leverages a Cinterion TX62 wireless module by Thales, designed for highly efficient, low-power IoT applications to deliver optimized bandwidth and performance. The Portenta Cat. M1/NB IoT GNSS Shield combines with the strong edge computing power of the Portenta H7 to enable the development of asset tracking and remote monitoring applications in industrial settings, as well as in agriculture, public utilities and smart cities. The shield offers cellular connectivity to both Cat. M1 and NB-IoT networks with the option to use eSIM technology. Easily track your valuables – across the city or worldwide – with your choice of GPS, GLONASS, Galileo or BeiDou. Features Change connectivity capabilities without changing the board Add NB-IoT, CAT. M1 and positioning to any Portenta product Possibility to create a small multiprotocol router (WiFi - BT + NB-IoT/CAT. M1) Greatly reduce communication bandwidth requirements in IoT applications Low-power module Compatible also with MKR boards Remote Monitoring Industrial and agricultural companies can leverage the Portenta Cat. M1/NB IoT GNSS Shield to remotely monitor gas detectors, optical sensors, machinery alarm systems, biological bug traps and more. Technology providers providing smart city solutions can compound the power and reliability of the Portenta H7 with the Portenta Cat. M1/NB IoT GNSS Shield, to connect data and automate actions for a truly optimized use of resources and enhanced user experience. Asset Monitoring Add monitoring capabilities to any asset by combining the performance and edge computing features of the Portenta family boards. The Portenta Cat. M1/NB IoT GNSS Shield is ideal to monitor valuable goods and also for monitoring industrial machinery and equipment. Specifications Connectivity Cinterion TX62 wireless module; NB-IoT - LTE CAT.M1; 3GPP Rel.14 Compliant Protocol LTE Cat. M1/NB1/NB2; UMTS BANDS: 1 / 2 / 3 / 4 / 5 / 8 / 12(17) / 13 / 18 / 19 / 20 / 25 / 26 / 27 / 28 / 66 / 71 / 85; LTE Cat.M1 DL: max. 300 kbps, UL: max. 1.1 Mbps; LTE Cat.NB1 DL: max. 27 kbps, UL: max. 63 kbps; LTE Cat.NB2 DL: max. 124 kbps, UL: max. 158 kbps Short messaging service (SMS) Point-to-point mobile terminated (MT) and mobile originated (MO) Text Mode; Protocol Data Unit (PDU) Mode Localization support GNSS capability (GPS/BeiDou/Galileo/GLONASS) Other Embedded IPv4 and IPv6 TCP/IP stack access; Internet Services: TCP server/client, UDP client, DNS, Ping, HTTP client, FTP client, MQTT client Secure Connection with TLS/DTLS Secure boot Dimensions 66 x 25.4 mm Operating temperature -40° C to +85° C (-104° F to 185°F) Downloads Datasheet Schematics

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The Portenta Vision Shield LoRa brings industry-rated features to your Portenta. This hardware add-on will let you run embedded computer vision applications, connect wirelessly via LoRa to the Arduino Cloud or your own infrastructure, and activate your system upon the detection of sound events. The shield comes with: a 320x320 pixels camera sensor: use one of the cores in Portenta to run image recognition algorithms using the OpenMV for Arduino editor long range 868/915 MHz LoRa wireless connectivity: get your Portenta H7 connected to the Internet of Things with low power consumption two on-board microphones for directional sound detection: capture and analyse sound in real-time JTAG connector: perform low-level debugging of your Portenta board or special firmware updates using an external programmer SD-Card connector: store your captured data in the card, or read configuration files The Vision Shield LoRa has been designed to work with the Arduino Portenta H7. The Portenta boards feature multicore 32-bit ARM Cortex processors running at hundreds of megahertz, with megabytes of program memory and RAM. Portenta boards come with WiFi and Bluetooth. Specifications Camera Himax HM-01B0 camera module (manufacturer site) Resolution 320 x 320 active pixel resolution with support for QVGA Image sensor High sensitivity 3.6μ BrightSense pixel technology Microphone 2x MP34DT05 (datasheet) Connectivity 868/915MHz ABZ-093 LoRa Module with ARM Cortex-M0+ (datasheet) Dimensions 66 x 25 mm Weight 8 g Downloads Datasheet Schematics

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