Search results for "maxim-integrated"
Get Started with the MAX78000FTHR Development Board
Build your own AI microcontroller applications from scratchThe MAX78000FTHR from Maxim Integrated is a small development board based on the MAX78000 MCU. The main usage of this board is in artificial intelligence applications (AI) which generally require large amounts of processing power and memory. It marries an Arm Cortex-M4 processor with a floating-point unit (FPU), convolutional neural network (CNN) accelerator, and RISC-V core into a single device. It is designed for ultra-low power consumption, making it ideal for many portable AI-based applications.This book is project-based and aims to teach the basic features of the MAX78000FTHR. It demonstrates how it can be used in various classical and AI-based projects. Each project is described in detail and complete program listings are provided. Readers should be able to use the projects as they are, or modify them to suit their applications. This book covers the following features of the MAX78000FTHR microcontroller development board: Onboard LEDs and buttons External LEDs and buttons Using analog-to-digital converters I²C projects SPI projects UART projects External interrupts and timer interrupts Using the onboard microphone Using the onboard camera Convolutional Neural Network
€ 32,95
Members € 29,66
Elektor Bundles Get Started with the MAX78000FTHR Bundle
The MAX78000FTHR from Maxim Integrated is a small development board based on the MAX78000 MCU. The main usage of this board is in artificial intelligence applications (AI) which generally require large amounts of processing power and memory. It marries an Arm Cortex-M4 processor with a floating-point unit (FPU), convolutional neural network (CNN) accelerator, and RISC-V core into a single device. It is designed for ultra-low power consumption, making it ideal for many portable AI-based applications. This book is project-based and aims to teach the basic features of the MAX78000FTHR. It demonstrates how it can be used in various classical and AI-based projects. Each project is described in detail and complete program listings are provided. Readers should be able to use the projects as they are, or modify them to suit their applications. This book covers the following features of the MAX78000FTHR microcontroller development board: Onboard LEDs and buttons External LEDs and buttons Using analog-to-digital converters I²C projects SPI projects UART projects External interrupts and timer interrupts Using the onboard microphone Using the onboard camera Convolutional Neural Network
€ 59,95€ 49,95
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Elektor Digital Get Started with the MAX78000FTHR Development Board (E-book)
Build your own AI microcontroller applications from scratch The MAX78000FTHR from Maxim Integrated is a small development board based on the MAX78000 MCU. The main usage of this board is in artificial intelligence applications (AI) which generally require large amounts of processing power and memory. It marries an Arm Cortex-M4 processor with a floating-point unit (FPU), convolutional neural network (CNN) accelerator, and RISC-V core into a single device. It is designed for ultra-low power consumption, making it ideal for many portable AI-based applications. This book is project-based and aims to teach the basic features of the MAX78000FTHR. It demonstrates how it can be used in various classical and AI-based projects. Each project is described in detail and complete program listings are provided. Readers should be able to use the projects as they are, or modify them to suit their applications. This book covers the following features of the MAX78000FTHR microcontroller development board: Onboard LEDs and buttons External LEDs and buttons Using analog-to-digital converters I²C projects SPI projects UART projects External interrupts and timer interrupts Using the onboard microphone Using the onboard camera Convolutional Neural Network
€ 27,95
Members € 22,36
JOY-iT JOY-iT HD35 USB Load Resistor (35 W)
The HD35 offers you a compact electronic USB-load-resistor with a performance capability up to 35 Watt. The present current can be easily read on the LCD-Display. Moreover, the device has an adjustable trimmer and is because of this capable of simulating different charging electronics like QC2.0, QC3.0, FCP and AFC 9V. The maximal voltage is up tp 25 V and the maximal current is up to 5 A. This is the reason that it is suitable for nearly every area of application. The built-in cooling component in connection with the temperature controlled fan unit is very effective in cooling down the complete device. With the help of the integrated button it is possible to activate or deactivate the configurated load very fast. Features USB Load Resistor up to 35 W Adjustable via built-in trimmer LCD display of actual current strength Buttons for switching the load on/off Simulation of different charging electronics: QC2.0 (5 V, 9 V, 20 V), QC3.0, FCP, AFC 9V Technical Details Operating Voltage 4 V - 25 V Operating Current 0.25 A - 5 A Power 35 W Measuring Temperature Range -10 °C - 40 °C Display 4 Digit Segment Display Display Color Red Fan Speed 8000 RPM ± 10% | Temperature-controlled Connections USB 2.0, MicroUSB, USB Type-C Dimensions 84 mm x 41 mm x 28 mm Weight 52 g
€ 24,95
Members € 22,46
Argon ONE M.2 Case for Raspberry Pi 4
The Argon ONE M.2 Case ups the ante by providing two full-sized HDMI ports, power management modes that allows for automatic booting, built-in IR support with streamlined options for configuration and integrated M.2 SATA SSD support through the USB 3 ports of the Raspberry Pi 4. Argon ONE M.2 Case extended support for M.2 SATA SSDs allows you to maximize the true potential speeds of your Raspberry Pi 4. You will now be able to boot via an M.2 SATA SSD for faster boot times and larger storage capacity compared to the traditional microSD card. Argon ONE M.2 is UASP supported for the Raspberry Pi 4 which means you can maximize the transfer speeds of your M.2 SATA Drive. It is compatible with any M.2 SATA SSD with Key-B and Key B&M. Features M.2 SATA SSD CompatibilityAccepts any size of M.2 SATA SSD with Key-B or Key-B&M UASP Supported for Raspberry Pi 4Maximizes the high speed data transfers for Raspberry Pi 4 Two Full-Sized HDMIImproves the dual-monitor support of the Raspberry Pi 4 for its video input Power Management ModesOffers 2 power management options with automatic booting or “Always ON Mode” Built-in IR SupportProgrammable IR support to the Raspberry Pi with streamlined options. Works out of the box with the Argon ONE Remote. Active CoolingSoftware Programmable 30 mm FAN via the Argon ONE software Passive CoolingAluminum alloy top case acts as a giant heatsink connected to the CPU of the Raspberry Pi 4 Cable ManagementRepositioned all ports to the back of the Raspberry Pi 4 to highlight its sleek and modern design.
€ 64,95
Members € 58,46
Arduino Arduino Pro Nicla Sense ME
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
€ 84,95
Members € 76,46
Waveshare Waveshare L76B GNSS Module for Raspberry Pi Pico
The Pico-GPS-L76B is a GNSS module designed for Raspberry Pi Pico, with multi satellite systems support including GPS, BDS, and QZSS. It has advantages such as fast positioning, high accuracy, and low power consumption, etc. Combined with the Raspberry Pi Pico, it's easy to use global navigating function.Features Standard Raspberry Pi Pico header, supports Raspberry Pi Pico series boards Multi satellite systems support: GPS, BDS, and QZSS EASY, self track prediction technology, help quick positioning AlwaysLocate, intelligent controller of periodic mode for power saving Supports D-GPS, SBAS (WAAS/EGNOS/MSAS/GAGAN) UART communication baudrate: 4800~115200bps (9600bps by default) Onboard battery holder, supports ML1220 rechargeable cell, for preserving ephemeris information and hot starts 4x LEDs for indicating the module operating status Comes with development resources and manual (Raspberry Pi Pico C/C++ and MicroPython examples) Specifications GNSS Frequency band:GPS L1 (1575.42 Mhz)BD2 B1 (1561.098 MHz) Channels: 33 tracking ch, 99 acquisition ch, 210 PRN ch C/A code SBAS: WAAS, EGNOS, MSAS, GAGAN Horizontal position accuracy(autonomous positioning) <2.5 m CEP Time-To-First-Fix @ -130 dBm(EASY enabled) Cold starts: <15s Warm starts: <5s Hot starts: <1s Sensitivity Acquisition: -148 dBm Tracking: -163 dBm Re-acquisition: -160 dBm Dynamic performance Altitude (max): 18000 m Velocity (max): 515 m/s Acceleration (max): 4 g Others Communication interface UART Baudrate 4800~115200bps (9600bps by default) Update rate 1 Hz (default), 10 Hz (max) Protocols NMEA 0183, PMTK Power supply voltage 5 V Operating current 13 mA Overall current consumption < 40 mA@5 V (Continue mode) Operating temperature -40℃ ~ 85℃ Dimensions 52 × 21 mm Included 1x Pico-GPS-L76B 1x GPS Antenna
€ 21,95
Members € 19,76
PiKVM PiKVM V3 KVM over IP for Raspberry Pi 4
PiKVM V3 is an open-source Raspberry Pi-based KVM over IP device. It will help you to manage servers or workstations remotely, whatever the state of the operating system or whether one is installed. PiKVM V3 allows you to turn on/off or restart your computer, configure the UEFI/BIOS, and even reinstall the OS using the virtual CD-ROM or flash drive. You can use your remote keyboard and mouse or PiKVM can simulate a keyboard, mouse, and a monitor, which are then presented in a web browser as if you were working on a remote system directly. Features HDMI Full HD capture based on the TC358743 chip (extra low latency ~100 ms and many features like compression control). OTG Keyboard & mouse; Mass Storage Drive emulation. Ability to simulate 'removal and insertion' for USB. Onboard ATX power control Onboard fan controller Real-time clock (RTC) RJ-45 and USB serial console port (to manage PiKVM OS or to connect with the server). Optional AVR-based HID (for some rare and strange motherboards whose BIOS doesn't understand the OTG emulated keyboard). Optional OLED screen to display network status or other desired information. Ready-made board. No need for soldering or breadboarding. PiKVM OS – the software is fully open. Included PiKVM V3 HAT board for Raspberry Pi 4 USB-C bridge board – to connect the HAT with Pi over USB-C ATX controller adapter board and wiring – to connect the HAT to the motherboard (if you want to manage power supply through hardware). 2 flat CSI cables Screws and brass standoffs Required Raspberry Pi 4 MicroSD card USB-C to USB-A cable HDMI cable Straight Ethernet cable (for the ATX expansion board connection) Power supply unit (5.1 V/3 A USB-C, officiel RPi power supply is recommended) Also available PiKVM Steel Case Downloads User Guide Images GitHub Links The PiKVM Project and Lessons Learned: Q&A with PiKVM creator and developer Maxim Devaev PiKVM: Raspberry Pi as a KVM Remote Control
€ 184,95
Members € 166,46
Elektor Labs DIY LiPo Supercharger Kit V2 (by GreatScott!)
This DIY LiPo Supercharger/Booster (developed the electronics engineer/YouTuber GreatScott! and produced by Elektor) can charge a single-cell LiPo battery and protect it against the effects of overvoltage, overload, and short-circuits. Additionally, it can boost the battery voltage to 5 V or 12 V. The boosted output voltage is protected by an ‘eFuse’ IC outputting 1.52 A at 5 V or 0.76 A at 12 V maximum.The charger part of the circuit needs a +5 V power supply which can be connected through USB-C, or simply two wires soldered to pads on the PCB.In addition, other connections can be soldered to pads on the PCB or by using single pinheaders.Included 1x Mainboard pre-assembled with the 4 ICs 15x Resistors 3x LEDs 13x Capacitors 2x Switches 1x USB-C on a breakout board 2x Diodes Please note: Battery is not included.The board uses a DC/DC Converter, an IC charger, and an e Fuse from Texas Instruments. The battery protection IC is from Xysemi and provides under-voltage lockout, over current protection, and reverse battery protection.The board is connected to the power and recharges the batteries via a USB-C connection.Specifications Battery Single-cell lithium-ion or lithium-polymer battery Input Voltage +5 V / 2 A max. Output Voltage 5 V / 1.52 A12 V / 0.76 A LiPo Protection XB8089D Overcharge Detection 4.250 V Overcharge Release 4.10 V Overdischarge Detection 2.50 V Overdischarge Release 3 V Overcurrent Detection 10.0 A Thermal Shutdown Auto-retry Enable/Undervoltage Lockout Rising: 1.2 V (typ.)Falling: 1.1 V (typ.)
€ 29,95€ 24,95
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SparkFun SparkFun GPS Dead Reckoning Breakout - NEO-M8U (Qwiic)
The NEO-M8U module is a 72-channel u-blox M8 engine GNSS receiver, meaning it can receive signals from the GPS, GLONASS, Galileo, and BeiDou constellations with ~2.5-meter accuracy. The module supports the concurrent reception of three GNSS systems. The combination of GNSS and integrated 3D sensor measurements on the NEO-M8U provide accurate, real-time positioning rates of up to 30Hz. Compared to other GPS modules, this breakout maximizes position accuracy in dense cities or covered areas. Even under poor signal conditions, continuous positioning is provided in urban environments and is also available during complete signal loss (e.g. short tunnels and parking garages). With UDR, position begins as soon as power is applied to the board, even before the first GNSS fix is available! Lock time is further reduced with an on-board rechargeable battery; you'll have backup power enabling the GPS to get a hot lock within seconds! Additionally, this u-blox receiver supports I²C (u-blox calls this Display Data Channel), making it perfect for the Qwiic compatibility, so we don't have to use up our precious UART ports. Utilizing our handy Qwiic system, no soldering is required to connect it to the rest of your system. However, we still have broken out 0.1'-spaced pins if you prefer to use a breadboard. U-blox based GPS products are configurable using the popular but dense, windows program called u-centre. Plenty of different functions can be configured on the NEO-M8U: baud rates, update rates, geofencing, spoofing detection, external interrupts, SBAS/D-GPS, etc. All of this can be done within the SparkFun Arduino Library! The SparkFun NEO-M8U GPS Breakout is also equipped with an on-board rechargeable battery that provides power to the RTC on the NEO-M8U. This reduces the time-to-first fix from a cold start (~26s) to a hot start (~1.5s). The battery will maintain RTC and GNSS orbit data without being connected to power for plenty of time. Features Integrated U.FL connector for use with an antenna of your choice 72-Channel GNSS Receiver 2.5 m Horizontal Accuracy 30 Hz Max Update Rate Time-To-First-Fix: Cold: 26 s Hot: 1.5 s Max Altitude: 50,000 m Max G: ≤4 Max Velocity: 500 m/s Velocity Accuracy: 0.5m/s Heading Accuracy: 1 degree Built-In Accelerometer and Gyroscope Time Pulse Accuracy: 30 ns 3.3 V VCC and I/O Current Consumption: ~29 mA Continuous Tracking, Default Concurrent Mode Software Configurable Geofencing Odometer Spoofing Detection External Interrupt Pin Control Low Power Mode Many others! Supports NMEA, UBX, and RTCM protocols over UART or I²C interfaces
€ 71,95
Members € 64,76
SparkFun SparkFun GPS-RTK Dead Reckoning pHAT for Raspberry Pi
The ZED-F9R module is a 184-channel u-blox F9 engine GNSS receiver, meaning it can receive signals from the GPS, GLONASS, Galileo, and BeiDou constellations with ~0.2-meter accuracy! That's right; such accuracy can be achieved with an RTK navigation solution when used with a correction source. Note that the ZED-F9R can only operate as a rover, so you will need to connect to a base station. The module supports the concurrent reception of four GNSS systems. The combination of GNSS and integrated 3D sensor measurements on the ZED-F9R provide accurate, real-time positioning rates of up to 30Hz. Compared to other GPS modules, this pHAT maximizes position accuracy in dense cities or covered areas. Even under poor signal conditions, continuous positioning is provided in urban environments and is also available during complete signal loss (e.g. short tunnels and parking garages). The ZED-F9R is the ultimate solution for autonomous robotic applications that require accurate positioning under challenging conditions. This u-blox receiver supports a few serial protocols. By default, we chose to use the Raspberry Pi's serial UART to communicate with the module. With pre-soldered headers, no soldering is required to stack the pHAT on a Raspberry Pi, NVIDIA Jetson Nano, Google Coral, or any single-board computer with the 2x20 form factor. We have also broken out a few 0.1'-spaced pins from the u-blox receiver. A Qwiic connector is also added in case you need to connect a Qwiic enabled device. U-blox based GPS products are configurable using the popular but dense, windows program called u-centre. Plenty of different functions can be configured on the ZED-F9R: baud rates, update rates, geofencing, spoofing detection, external interrupts, SBAS/D-GPS, etc. The SparkFun ZED-F9R GPS pHAT is also equipped with an on-board rechargeable battery that provides power to the RTC on the ZED-F9R. This reduces the time-to-first fix from a cold start (~24s) to a hot start (~2s). The battery will maintain RTC and GNSS orbit data without being connected to power for plenty of time. Features 1 x Qwiic Connector Integrated U.FL connector for use with an antenna of your choice Concurrent reception of GPS, GLONASS, Galileo and BeiDou 184-Channel GNSS Receiver Receives both L1C/A and L2C bands Horizontal Position Accuracy: 0.20 m with RTK Max Navigation Rate: Up to 30Hz Time to First Fix Cold: 24 s Hot: 2 s Operational Limits Max G: ≤4 G Max Altitude: 50 km Max Velocity: 500 m/s Velocity Accuracy: 0.5 m/s Heading Accuracy: 0.2 degrees Built-In Accelerometer and Gyroscope Time Pulse Accuracy: 30ns Voltage: 5 V or 3.3 V, but all logic is 3.3 V Current: ~85mA to ~130mA (varies with constellations and tracking state) Software Configurable Geofencing Odometer Spoofing Detection External Interrupt Pin Control Low Power Mode Supports NMEA, UBX, and RTCM protocols over UART
€ 299,00
Members € 269,10
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, by Jean-François Simon The RC-RICK-868-EV Wireless Modem: A Compelling Addition to Your Workbench
The RC-RICK-868 is a radio modem with a UART interface using LoRa modulation, designed for easy point-to-point communication. Let's take a look.