Search results for "Arduino c p"
C Programming with Arduino
Technology is constantly changing. New microcontrollers become available every year. The one thing that has stayed the same is the C programming language used to program these microcontrollers. If you would like to learn this standard language to program microcontrollers, then this book is for you! Arduino is the hardware platform used to teach the C programming language as Arduino boards are available worldwide and contain the popular AVR microcontrollers from Atmel. Atmel Studio is used as the development environment for writing C programs for AVR microcontrollers. It is a full-featured integrated development environment (IDE) that uses the GCC C software tools for AVR microcontrollers and is free to download. At a glance: Start learning to program from the very first chapter No programming experience is necessary Learn by doing – type and run the example programs A fun way to learn the C programming language Ideal for electronic hobbyists, students and engineers wanting to learn the C programming language in an embedded environment on AVR microcontrollers Use the free full-featured Atmel Studio IDE software for Windows Write C programs for 8-bit AVR microcontrollers as found on the Arduino Uno and MEGA boards Example code runs on Arduino Uno and Arduino MEGA 2560 boards and can be adapted to run on other AVR microcontrollers or boards Use the AVR Dragon programmer / debugger in conjunction with Atmel Studio to debug C programs
€ 44,95
Members € 40,46
Arduino Arduino Nano
The Arduino Nano is a small, complete, and breadboard-friendly board based on the ATmega328 (Arduino Nano 3.x). It has more or less the same functionality of the Arduino Duemilanove but in a different package. It lacks only a DC power jack and works with a Mini-B USB cable instead of a standard one. The Nano was designed and is being produced by Gravitech. Specifications Microcontroller ATmega328 Operating Voltage (logic level) 5 V Input Voltage (recommended) 7-12 V Input Voltage (limits) 6-20 V Digital I/O Pins 14 (of which 6 provide PWM output) Analog Input Pins 8 DC Current per I/O Pin 40 mA Flash Memory 16 KB (ATmega168) or 32 KB (ATmega328) of which 2 KB used by bootloader SRAM 1 KB (ATmega168) or 2 KB (ATmega328) EEPROM 512 bytes (ATmega168) or 1 KB (ATmega328) Clock Speed 16 MHz Dimensions 0.73 x 1.70" (18 x 45 mm) Power The Arduino Nano can be powered via the Mini-B USB connection, 6-20 V unregulated external power supply (pin 30), or 5 V regulated external power supply (pin 27). The power source is automatically selected to the highest voltage source. Memory The ATmega168 has 16 KB of flash memory for storing code (of which 2 KB is used for the bootloader), 1 KB of SRAM and 512 bytes of EEPROM The ATmega328 has 32 KB of flash memory for storing code, (also with 2 KB used for the bootloader), 2 KB of SRAM and 1 KB of EEPROM. Input and Output Each of the 14 digital pins on the Nano can be used as an input or output, using pinMode(), digitalWrite(), and digitalRead() functions. They operate at 5 V. Each pin can provide or receive a maximum of 40 mA and has an internal pull-up resistor (disconnected by default) of 20-50 kOhms. Communication The Arduino Nano has a number of facilities for communicating with a computer, another Arduino, or other microcontrollers. The ATmega168 and ATmega328 provide UART TTL (5V) serial communication, which is available on digital pins 0 (RX) and 1 (TX). An FTDI FT232RL on the board channels this serial communication over USB and the FTDI drivers (included with the Arduino software) provide a virtual com port to software on the computer. The Arduino software includes a serial monitor which allows simple textual data to be sent to and from the Arduino board. The RX and TX LEDs on the board will flash when data is being transmitted via the FTDI chip and USB connection to the computer (but not for serial communication on pins 0 and 1). A SoftwareSerial library allows for serial communication on any of the Nano's digital pins. Programming The Arduino Nano can be programmed with the Arduino software (download). The ATmega168 or ATmega328 on the Arduino Nano comes with a bootloader that allows you to upload new code to it without the use of an external hardware programmer. It communicates using the original STK500 protocol (reference, C header files). You can also bypass the bootloader and program the microcontroller through the ICSP (In-Circuit Serial Programming) header using Arduino ISP or similar; see these instructions for details. Automatic (Software) Reset Rather than requiring a physical press of the reset button before an upload, the Arduino Nano is designed in a way that allows it to be reset by software running on a connected computer. One of the hardware flow control lines (DTR) of theFT232RL is connected to the reset line of the ATmega168 or ATmega328 via a 100 nF capacitor. When this line is asserted (taken low), the reset line drops long enough to reset the chip. The Arduino software uses this capability to allow you to upload code by simply pressing the upload button in the Arduino environment. This means that the bootloader can have a shorter timeout, as the lowering of DTR can be well-coordinated with the start of the upload.
€ 22,95
Members € 20,66
Arduino Official Arduino USB-C Cable (2-in-1)
Now you can connect your Arduino boards with the official Arduino USB cable. Through a USB-C to USB-C with a USB-A adapter connection, this data USB cable can easily connect your Arduino boards with your chosen programming device. The Arduino USB cable has a nylon braided jacket in the typical Arduino colors white and teal. The connectors have an aluminum shell that protects your cable from harm at the same time as looking cool. Length: 100 cm Aluminium shell with logo Nylon braided jacket white and teal
€ 12,95
Members € 11,66
Arduino Arduino Nano ESP32
The Arduino Nano ESP32 (with and without headers) is a Nano form factor board based on the ESP32-S3 (embedded in the NORA-W106-10B from u-blox). This is the first Arduino board to be based fully on an ESP32, and features Wi-Fi, Bluetooth LE, debugging via native USB in the Arduino IDE as well as low power. The Nano ESP32 is compatible with the Arduino IoT Cloud, and has support for MicroPython. It is an ideal board for getting started with IoT development. Features Tiny footprint: Designed with the well-known Nano form factor in mind, this board's compact size makes it perfect for embedding in standalone projects. Wi-Fi and Bluetooth: Harness the power of the ESP32-S3 microcontroller, well-known in the IoT realm, with full Arduino support for wireless and Bluetooth connectivity. Arduino and MicroPython support: Seamlessly switch between Arduino and MicroPython programming with a few simple steps. Arduino IoT Cloud compatible: Quickly and easily create IoT projects with just a few lines of code. The setup takes care of security, allowing you to monitor and control your project from anywhere using the Arduino IoT Cloud app. HID support: Simulate human interface devices, such as keyboards or mice, over USB, opening up new possibilities for interacting with your computer. Specifications Microcontroller u-blox NORA-W106 (ESP32-S3) USB connector USB-C Pins Built-in LED pins 13 Built-in RGB LED pins 14-16 Digital I/O pins 14 Analog input pins 8 PWM pins 5 External interrupts All digital pins Connectivity Wi-Fi u-blox NORA-W106 (ESP32-S3) Bluetooth u-blox NORA-W106 (ESP32-S3) Communication UART 2x I²C 1x, 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) 6-21 V Source Current per I/O pin 40 mA Sink Current per I/O pin 28 mA Clock speed Processor Up to 240 MHz Memory ROM 384 kB SRAM 512 kB External Flash 128 Mbit (16 MB) Dimensions 18 x 45 mm Downloads Datasheet Schematics
€ 23,95
Members € 21,56
Arduino Arduino Portenta HAT Carrier
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
€ 54,95
Members € 49,46
Elektor Digital C Programming with Arduino (E-BOOK)
Technology is constantly changing. New microcontrollers become available every year. The one thing that has stayed the same is the C programming language used to program these microcontrollers. If you would like to learn this standard language to program microcontrollers, then this book is for you! Arduino is the hardware platform used to teach the C programming language as Arduino boards are available worldwide and contain the popular AVR microcontrollers from Atmel. Atmel Studio is used as the development environment for writing C programs for AVR microcontrollers. It is a full-featured integrated development environment (IDE) that uses the GCC C software tools for AVR microcontrollers and is free to download. At a glance: Start learning to program from the very first chapter No programming experience is necessary Learn by doing – type and run the example programs A fun way to learn the C programming language Ideal for electronic hobbyists, students and engineers wanting to learn the C programming language in an embedded environment on AVR microcontrollers Use the free full-featured Atmel Studio IDE software for Windows Write C programs for 8-bit AVR microcontrollers as found on the Arduino Uno and MEGA boards Example code runs on Arduino Uno and Arduino MEGA 2560 boards and can be adapted to run on other AVR microcontrollers or boards Use the AVR Dragon programmer / debugger in conjunction with Atmel Studio to debug C programs
€ 33,95
Members € 27,16
Arduino Arduino Pro Portenta Machine Control
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
€ 359,00
Members € 323,10
Arduino Arduino Giga Display Shield
The Giga Display Shield is a touch screen solution designed to effortlessly deploy graphic interfaces in your projects. Leveraging the new pin header connector in the middle of Giga R1 WiFi, this shield offers seamless integration and enhanced functionalities. With the Giga Display Shield, you gain access to an array of features, including a digital microphone, 6-axis IMU, and Arducam connector. These added capabilities allow you to fully utilize the other 54 available pins, making it incredibly convenient to create handheld devices or dashboards to control your project. Specifications Display KD040WVFID026-01-C025A Size 3.97” Resolution 480x800 RGB Color 16.7M Touch Mode Five points and Gestures Interface I²C Sensors IMU BMI270 Microphone MP34DT06JTR Downloads Datasheet Schematics
€ 84,95
Members € 76,46
Arduino Arduino Uno R4 WiFi
The Arduino Uno R4 is powered by the Renesas RA4M1 32-bit ARM Cortex-M4 processor, providing a significant boost in processing power, memory, and functionality. The WiFi version comes with an ESP32-S3 WiFi module in addition to the RA4M1, expanding creative opportunities for makers and engineers. The Uno R4 Minima is an affordable option for those who don't need the additional features. The Arduino Uno R4 runs at 48 MHz, which provides a 3x increase over the popular Uno R3. Additionally, SRAM has been upgraded from 2 kB to 32 kB, and flash memory from 32 kB to 256 kB to support more complex projects. Responding to community feedback, the USB port is now USB-C, and the maximum power supply voltage has been raised to 24 V with an enhanced thermal design. The board includes a CAN bus and an SPI port, enabling users to reduce wiring and perform parallel tasks by connecting multiple shields. A 12-bit analog DAC is also provided on the board. The Arduino Uno R4 comes in 2 versions (Minima and WiFi) and offers the following new features compared to the Uno R3: Arduino Uno R4 Minima Arduino Uno R4 WiFi USB-C connector USB-C connector RA4M1 from Renesas (Cortex-M4) RA4M1 from Renesas (Cortex-M4) HID device (emulate a mouse or a keyboard) HID device (emulate a mouse or a keyboard) Improved power section (up to 24 V through VIN) Improved power section (up to 24 V through VIN) CAN bus CAN bus DAC (12 bits) DAC (12 bits) Op amp Op amp WiFi/Bluetooth LE Fully-addressable LED matrix (12x8) Qwiic I²C connector RTC (with support for a buffer battery) Runtime errors diagnostics Model Comparison Uno R3 Uno R4 Minima Uno R4 WiFi Microcontroller Microchip ATmega328P (8-bit AVR RISC) Renesas RA4M1 (32-bit ARM Cortex-M4) Renesas RA4M1 (32-bit ARM Cortex-M4) Operating Voltage 5 V 5 V 5 V Input Voltage 6-20 V 6-24 V 6-24 V Digital I/O Pins 14 14 14 PWM Digital I/O Pins 6 6 6 Analog Input Pins 6 6 6 DC Current per I/O Pin 20 mA 8 mA 8 mA Clock Speed 16 MHz 48 Mhz 48 Mhz Flash Memory 32 KB 256 KB 256 KB SRAM 2 KB 32 KB 32 KB USB USB-B USB-C USB-C DAC (12 bit) – 1 1 SPI 1 2 2 I²C 1 2 2 CAN – 1 1 Op amp – 1 1 SWD – 1 1 RTC – – 1 Qwiic I²C connector – – 1 LED Matrix – – 12x8 (96 red LEDs) LED_BUILTIN 13 13 13 Dimensions 68.6 x 53.4 mm 68.9 x 53.4 mm 68.9 x 53.4 mm Downloads Datasheet Schematics
€ 29,95
Members identical
Arduino Arduino Pro Portenta Max Carrier
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
€ 439,00
Members € 395,10
Arduino Arduino Pro Portenta H7
Portenta H7 follows the Arduino MKR form factor, but enhanced with the Portenta family 80-pin high-density connector. Program it with high-level languages and AI while performing low-latency operations on its customizable hardware. Portenta H7 simultaneously runs high level code along with real time tasks. The design includes two processors that can run tasks in parallel. For example, is possible to execute Arduino compiled code along with MicroPython one, and have both cores to communicate with one another. The Portenta functionality is two-fold, it can either be running like any other embedded microcontroller board, or as the main processor of an embedded computer. Portenta can easily run processes created with TensorFlow Lite, you could have one of the cores computing a computer vision algorithm on the fly, while the other could be making low-level operations like controlling a motor, or acting as a user interface. Use Portenta when performance is key, among other cases, we envision it to be part of: High-end industrial machinery Laboratory equipment Computer vision PLCs Industry-ready user interfaces Robotics controller Mission-critical devices Dedicated stationary computer High-speed booting computation (ms) Two Parallel Cores H7's main processor is the dual core STM32H747 including a Cortex M7 running at 480 MHz and a Cortex-M4 running at 240 MHz. The two cores communicate via a Remote Procedure Call mechanism that allows calling functions on the other processor seamlessly. Both processors share all the in-chip peripherals and can run: Arduino sketches on top of the ARM Mbed OS Native Mbed applications MicroPython / JavaScript via an interpreter TensorFlow Lite Graphics Accelerator Probably one of the most exciting features of the Portenta H7 is the possibility of connecting an external monitor to build your own dedicated embedded computer with a user interface. This is possible thanks to the STM32H747 processor's on-chip GPU, the Chrom-ART Accelerator. Besides the GPU, the chip includes a dedicated JPEG encoder and decoder. A new standard for pinouts The Portenta family adds two 80-pin high density connectors at the bottom of the board. This ensures scalability for a wide range of applications by simply upgrading your Portenta board to the one suiting your needs. On-board Connectivity The onboard wireless module allows to simultaneously manage WiFi and Bluetooth connectivity. The WiFi interface can be operated as an Access Point, as a Station or as a dual mode simultaneous AP/STA and can handle up to 65 Mbps transfer rate. Bluetooth interface supports Bluetooth Classic and Bluetooth Low Energy. It is also possible to expose a series of different wired interfaces like UART, SPI, or I²C, both through some of the MKR styled connectors, or through the new Arduino industrial 80-pin connector pair. The 80-pin connector pair provides additional features including Ethernet. USB-C Multipurpose Connector The board's programming connector is a USB-C port that can also be used to power the board, as a USB Hub, to connect a DisplayPort monitor, or to deliver power to OTG connected devices. Specifications The Arduino Portenta H7 is based on the STM32H747 microcontroller, XI series. Microcontroller STM32H747XI dual Cortex-M7+M4 32bit low power ARM MCU (datasheet) Radio module Murata 1DX dual WiFi 802.11b/g/n 65 Mbps and Bluetooth (Bluetooth Low Energy. 5 via Cordio stack, Bluetooth Low Energy 4.2 via Arduino Stack) (datasheet) Secure element (default) NXP SE0502 (datasheet) Board power supply (USB/VIN) 5 V Supported battery Li-Po Single Cell, 3.7 V, 700 mAh Minimum (integrated charger) Circuit operating voltage 3.3 V Display connector MIPI DSI host & MIPI D-PHY to interface with low-pin count large display GPU Chrom-ART graphical hardware Accelerator Timers 22x timers and watchdogs UART 4x ports (2 with flow control) Ethernet PHY 10 / 100 Mbps (through expansion port only) SD card Interface for SD Card connector (through expansion port only) Operational temperature -40 °C to +85 °C MKR headers Use any of the existing industrial MKR shields on it High-density connectors Two 80-pin connectors will expose all of the board's peripherals to other devices Camera interface 8-bit, up to 80 MHz ADC 3x ADCs with 16-bit max. resolution (up to 36 channels, up to 3.6 MSPS) DAC 2x 12-bit DAC (1 MHz) USB-C Host / Device, DisplayPort out, High / Full Speed, Power delivery Downloads Datasheet Schematics Pinout
€ 129,95
Members € 116,96
Arduino Arduino Science Kit Rev3
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
€ 239,00
Members € 215,10