The Smart USB Soldering Iron Kit is a compact, cordless solution designed for precision and portability. Featuring intelligent three-speed temperature control (300-450°C) with an easy-to-read LED display, it heats up in just 10 seconds and melts solder in as little as 6 seconds. The 1000 mAh rechargeable battery delivers up to 30 minutes of continuous use, making it ideal for quick repairs, electronics projects, and DIY tasks. With a plug-and-play, replaceable tip and a high-temperature-resistant insulated shell, it’s safe, user-friendly, and perfect for both beginners and professionals on the go. Features Three-Speed Intelligent Temperature Adjustment: Features an LED display screen with adjustable temperatures between 300-450°C (572-842°F). Easily switch between Celsius and Fahrenheit. Integrated Plug-In Soldering Iron Tip: Plug-and-play design. The tip can be replaced by simply unscrewing it, ensuring quick and convenient operation. Safe and Durable Design: High-temperature-resistant, insulated shell for enhanced safety during use. Battery Capacity: Equipped with a rechargeable 1000 mAh battery that supports up to 30 minutes of continuous operation on a full charge – ideal for everyday tasks. Efficient Performance: 8 W power with an integrated heating core for rapid heat-up. Melts tin in just 6 seconds, providing excellent thermal conductivity. Easy to Use: After powering on via USB, set your desired temperature. The soldering iron heats up in 10 seconds. Once finished, place the tip on the stand—it cools down within 1 minute. Perfect for beginners, hobbyists, basic home repairs, and training engineers. Cordless Innovation: This cordless soldering kit includes a built-in rechargeable lithium-ion battery, eliminating the need for cables. Versatile use for circuit board soldering, electrical repairs, jewelry making, metal crafts, computer maintenance, and DIY projects. Specifications Adjustable Temperature: 300-450°C (572-842°F) Tin Melting Time: <15 seconds Working Voltage: 5 V Power Output: 8 W Battery Capacity: 1000 mAh Auto Sleep Function: Activates after 10 minutes of inactivity Charging Time: Approx. 90 minutes Battery Life: Up to 30 minutes continuous use Charging Interface: USB-C Main Material: Aluminum alloy Dimensions: 190 x 16 mm (7.4 x 0.6") Included 1x USB Soldering Iron 1x Soldering Tip 1x Soldering Rosin 1x Soldering Iron Holder (with Sponge) 1x USB-C Charging Cable 1x Solder Wire 1x Storage Box

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T80-B (T80-D08) Soldering Tip for Soldering Station AE970D (0.8 mm, pointed)

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The Data Logging Carrier Board breaks out connections for I²C via a Qwiic connector or standard 0.1'-spaced PTH pins along with SPI and serial UART connections for logging data from peripheral devices using those communication protocols. The Data Logging Carrier Board allows you to control power to both the Qwiic connector on the board and a dedicated 3.3 V power rail for non-Qwiic peripherals so you can pick and choose when to power the peripherals you are monitoring the data from. It also features a charging circuit for single-cell Lithium-ion batteries along with a separate RTC battery-backup circuit to maintain power to a real-time clock circuit on your Processor Board. Features M.2 MicroMod Connector microSD socket USB-C Connector 3.3 V 1 A Voltage Regulator Qwiic Connector Boot/Reset Buttons RTC Backup Battery & Charge Circuit Independent 3.3 V regulators for Qwiic bus and peripheral add-ons Controlled by digital pins on Processor Board to enable low power sleep modes Phillips #0 M2.5 x 3 mm screw included

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This board is an all-digital conversion of Raspberry Pi's VGA reference design, great for if you want to start hacking on video and/or audio output from a Raspberry Pi Pico and piping it straight into a modern monitor.Features HDMI connector PCM5100A DAC for line out audio over I²S (datasheet) SD card slot Reset button Socket headers to install your Raspberry Pi Pico Three user-controllable switches Rubber feet Compatible with Raspberry Pi Pico No soldering required (as long as your Pico has header pins attached) Programmable with C/C++ Note: Raspberry Pi Pico is not included. Your Pico will need to have pin headers soldered to it (with the pins pointing downwards) to attach to our add-on boards.Downloads Schematic GitHub

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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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If you are looking for a simple way to learn soldering, or just want to make a small gadget that you can carry, this set is a great opportunity. Reaction game is an educational kit which teaches you how to solder, and in the end, you get to have your own small game. The goal of the game is to press the button next to the LED as soon as it turns on. With every correct answer, the game gets a bit harder – the time you have to press the button shortens. How many correct answers can you get? It’s based on ATtiny404 microcontroller, programmed in Arduino. At its back, you’ll find CR2032 battery which makes the kit portable. There’s keychain holder as well. Soldering process is easy enough based on the mark on the PCB. Included 1x PCB 1x ATtiny404 microcontroller 4x LEDs 4x Pushbuttons 1x Switch 4x Resistors (330 ohm) 1x CR2032 battery holder 1x Battery CR2032 1x Keychain holder

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Voice recognition, always-on voice commands, gesture, or image recognition are possible with TensorFlow applications. The cloud is impressively robust, but all-the-time connection requires power and connectivity that may not be available. Edge computing handles discrete tasks such as determining if someone said 'yes' and responds accordingly. The audio analysis is done on the MicroMod combination rather than on the web. This dramatically reduces costs and complexity while limiting potential data privacy leaks. This board features two MEMS microphones (one with a PDM interface, one with an I²S interface), an ST LIS2DH12 3-axis accelerometer, a connector to interface to a camera (sold separately), and a Qwiic connector. A modern USB-C connector makes programming easy and we've exposed the JTAG connector for more advanced users who prefer to use the power and speed of professional tools. We've even added a convenient jumper to measure current consumption for low power testing. Features M.2 MicroMod Keyed-E H4.2mm 65 pins SMD Connector 0.5mm Digital I²C MEMS Microphone PDM Invensense ICS-43434 (COMP) Digital PDM MEMS Microphone PDM Knowles SPH0641LM4H-1 (IC) ML414H-IV01E Lithium Battery for RTC ST LIS2DH12TR Accelerometer (3-axis, ultra-low-power) 24 Pin 0.5mm FPC Connector (Himax camera connector) USB-C Qwiic connector MicroSD socket Phillips #0 M2.5x3mm screw included

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Grove - Time of Flight Distance Sensor-VL53L0X is a high speed, high accuracy and long range distance sensor based on VL53L0X. The VL53L0X is a new generation Time-of-Flight (ToF) laser-ranging module and it is one of the smallest on the market today. It provides accurate distance measurement independent of the target reflectances, making it superior to other conventional technologies. It can measure absolute distances up to 2 m, raising the standards in ranging performance levels and allowing various new applications. The VL53L0X integrates a leading-edge SPAD array (Single Photon Avalanche Diodes) and embeds ST’s second generation Flight SenseTM patented technology. The VL53L0X’s 940 nm VCSEL emitter (Vertical-Cavity Surface-Emitting Laser), is totally invisible to the human eye, coupled with internal physical infrared filters, it enables longer ranging distances, higher immunity to ambient light, and better robustness to cover glass optical crosstalk. Features VCSEL driver Ranging sensor with advanced embedded microcontroller Advanced embedded optical cross-talk compensation to simplify cover glass selection Safe for eyes: Class 1 laser device compliant with latest standard IEC 60825-1:2014 - 3rd edition Single power supply I²C interface for device control and data transfer Xshutdown (reset) and interrupt GPIO Programmable I²C address Working voltage: 3.3 V / 5 V Working temperature: 20 ℃ - 70 ℃ Recommended measurement distance: 30 mm - 1000 mm Default I²C address: 0x52 Included 1x Grove - Time of Flight Distance Sensor-VL53L0X 1x Grove Cable

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This module includes an integrated trace antenna, fits the IC to an FCC-approved footprint, and includes decoupling and timing mechanisms that would need to be designed into a circuit using the bare nRF52840 IC. The Bluetooth transceiver included on the nRF52840 boasts a BT 5.1 stack. It supports Bluetooth 5, Bluetooth mesh, IEEE 802.15.4 (Zigbee & Thread) and 2.4Ghz RF wireless protocols (including Nordic's proprietary RF protocol) allowing you to pick which option works best for your application. Features ARM Cortex-M4 CPU with a floating-point unit (FPU) 1MB internal Flash -- For all of your program, SoftDevice, and file-storage needs! 256kB internal RAM -- For your stack and heap storage. Integrated 2.4GHz radio with support for: Bluetooth Low Energy (BLE) -- With peripheral and/or central BLE device support Bluetooth 5 -- Mesh Bluetooth! ANT -- If you want to turn the device into a heart-rate or exercise monitor. Nordic's proprietary RF protocol -- If you want to communicate, securely, with other Nordic devices. Every I/O peripheral you could need. USB -- Turn your nRF52840 into a USB mass-storage device, use a CDC (USB serial) interface, and more. UART -- Serial interfaces with support for hardware flow-control if desired. I²C -- Everyone's favourite 2-wire bi-directional bus interface SPI -- If you prefer the 3+-wire serial interface Analogue-to-digital converters (ADC) -- Eight pins on the nRF52840 Mini Breakout support analogue inputs PWM -- Timer support on any pin means PWM support for driving LEDs or servo motors. Real-time clock (RTC) -- Keep close track of seconds and milliseconds, also supports timed deep-sleep features. Three UARTs Primary tied to USB interface. Two hardware UARTs. Two I²C Buses Two SPI Buses Secondary SPI Bus primarily used for Flash IC. PDM Audio Processing Two Analog Inputs Two Dedicated Digital I/O Pins Two Dedicated PWM Pins Eleven General Purpose I/O Pins

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This programmer is specifically designed for burning bootloaders (without a computer) on Arduino-compatible ATmega328 development boards. Simply plug the programmer into the ICSP interface to re-burn the bootloader. It’s also compatible with new chips, provided the IC is functional. Note: Burning a bootloader erases all previous chip data. Features Working voltage: 3.1-5.3 V Working current: 10 mA Compatible with Arduino Nano based boards (ATmega328) Dimensions: 39.6 x 15.5 x 7.8 mm

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Love the Cytron Maker Pi Pico (SKU 19706) but can't fit it into your project? Now there is the Cytron Maker Pi Pico Mini W. Powered by the awesome Raspberry Pi Pico W, it also inherited most of the useful features from its bigger sibling such as GPIO status LEDs, WS2812B Neopixel RGB LED, passive piezo buzzer, and not forget the user button and reset button. Features Powered by Raspberry Pi Pico W Single-cell LiPo connector with overcharge / over-discharge protection circuit, rechargeable via USB. 6x Status indicator LEDs for GPIOs 1x Passive piezo buzzer (Able to play musical tone or melody) 1x Reset button 1x User programmable button 1x RGB LEDs (WS2812B Neopixel) 3x Maker Ports, compatible with Qwiic, STEMMA QT, and Grove (via conversion cable) Support Arduino IDE, CircuitPython and MicroPython Dimension: 23.12 x 53.85 mm Included 1x Maker Pi Pico Mini W (pre-soldered Raspberry Pi Pico W with preloaded CircuitPython) 3x Grove to JST-SH (Qwiic / STEMMA QT) Cable Downloads Maker Pi Pico Mini Datasheet Maker Pi Pico Mini Schematic Maker Pi Pico Mini Pinout Diagram Official Raspberry Pi Pico Page Getting started with Raspberry Pi Pico CircuitPython for Raspberry Pi Pico Raspberry Pi Pico Datasheet RP2040 Datasheet Raspberry Pi Pico Python SDK Raspberry Pi Pico C/C++ SDK

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T80-D (T80-D12) Soldering Tip for Soldering Station AE970D (1.2 mm, chisel)

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This Grove CAN-BUS Module based on GD32E103 adopts a brand-new design, uses the cost-effective and high-performance GD32E103 microcontroller as the main control and cooperates with a firmware we wrote to complete the function of the serial port to CAN FD. Features Support CAN communication: Implements CAN FD at up to 5 Mb/s Easy to program: Support AT command which enables simple serial port programming Grove ecosystem: 20 x 40 x 10 mm small size, 4-pin Grove connector to plug and play, Arduino compatible This Grove CAN-BUS Module supports CAN FD(CAN with Flexible Data-Rate) communication, which is an extension to the original CAN protocol as specified in ISO 11898-1 that responds to increased bandwidth requirements in automotive networks. In CAN FD, the data rate (i.e. number of bits transmitted per second) is increased to be 5 times faster than the classic CAN (5 Mbit/s for the data payload only, the arbitration bit rate is still limited to 1Mbit/s for compatibility). It supports AT command which enables simple serial port programming. This Grove CAN-BUS Module is based on GD32E103 with a frequency up to 120 MHz. It has a flash size from 64 KB to 128 KB and an SRAM size from 20 KB to 32 KB. Applications Car hacking: allows different parts of the vehicle to talk to each other, including the engine, the transmission, and the brakes. Windows, doors, and mirror adjustment. 3D Printers Building automation Lighting control systems Medical instruments and equipment Specifications MCU GD32E103 UART baud rate Up to 115200 (default 9600) CAN FD baud rate Up to 5 Mb/s Indicator TX and RX led Working voltage 3.3 V Grove connector 4-pin Grove connector to plug and play Size 20 x 40 x 10 mm Downloads Datasheet GitHub

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This FeatherWing will make it easy to add data logging to any Feather Board you might have. You get both an I²C real-time clock (PCF8523) with 32 KHz crystal and battery backup, and a microSD socket that connects to the SPI port pins (+ extra pin for CS). Note: FeatherWing doesn't come with a microSD card. A CR1220 coin cell is required to use the RTC battery-backup capabilities. If you're not using the RTC part of the FeatherWing, a battery is not required. To talk to the microSD card socket Arduino's default SD library is recommended. Some light soldering is required to attach the headers onto the Wing. Pinouts Power pins   On the bottom row, the 3.3 V (second from left) and GND (fourth from left) pin are used to power the SD card and RTC (to take a load off the coin cell battery when main power is available) RTC & I²C Pins In the top right SDA (rightmost) and SCL (to the left of SDA) are used to talk to the RTC chip. SCL - I²C clock pin to connect to your microcontroller's I2C clock line. This pin has a 10 kΩ pull-up resistor to 3.3 V SDA - I²C data pin to connect to your microcontroller's I2C data line. This pin has a 10 kΩ pull-up resistor to 3.3 V There's also a breakout for INT which is the output pin from the RTC. It can be used as an interrupt output or it could also be used to generate a square wave. Note that this pin is an open drain - you must enable the internal pull-up on whatever digital pin it is connected to. SD & SPI Pins Starting from the left you've got SPI Clock (SCK) - output from feather to wing SPI Master Out Slave In (MOSI) - output from feather to wing SPI Master In Slave Out (MISO) - input from wing to feather These pins are in the same location on every Feather. They are used for communicating with the SD card. When the SD card is not inserted, these pins are completely free.

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The JOY-iT Armor Case BLOCK is a robust aluminum enclosure designed specifically for the Raspberry Pi 5. It offers excellent protection against heat and physical shocks, making it suitable for challenging environments. Its compact design ensures that it doesn't require additional space, allowing for seamless integration into existing projects. The case includes a large heatsink to enhance cooling efficiency. Installation is straightforward, with four screws (included) securing the case to the Raspberry Pi. Specifications Material CNC milled aluminum alloy Cooling performance Idle: ~39°CFull load: ~75°C Special features Large heat sink, protection against shocks and heat with the same volume as without housing Dimensions (top side) 69 x 56 x 15,5 mm Dimensions (bottom side) 87 x 56 x 7,5 mm

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What's with the silkscreen labels? They're all over the place. We decided to label the pins as they are assigned on the Apollo3 IC itself. This makes finding the pin with the function you desire a lot easier. Have a look at the full pin map from the Apollo3 datasheet. If you really need to test out the 4-bit SPI functionality of the Artemis, you're going to need to access pins 4, 22, 23, and 26. Need to try out the differential ADC port 1? Pins 14 and 15. The RedBoard Artemis ATP will allow you to flex the impressive capabilities of the Artemis module. The RedBoard Artemis ATP has the improved power conditioning and USB to serial that we've refined over the years on our RedBoard line of products. A modern USB-C connector makes programming easy. A Qwiic connector makes I²C easy. The ATP is fully compatible with SparkFun's Arduino core and can be programmed easily under the Arduino IDE. We've exposed the JTAG connector for more advanced users who prefer to use the power and speed of professional tools. If you need a lot of a GPIO with a simple program, ready to go to the market module, the ATP is the fix you need. We've added a digital MEMS microphone for folks wanting to experiment with always-on voice commands with TensorFlow and machine learning. We've even added a convenient jumper to measure current consumption for low power testing. With 1 MB flash and 384k RAM, you'll have plenty of room for your sketches. The Artemis module runs at 48 MHz with a 96 MHz turbo mode available and with Bluetooth to boot! Features Arduino Mega Footprint 1M Flash / 384k RAM 48MHz / 96MHz turbo available 6uA/MHz (operates less than 5mW at full operation) 48 GPIO - all interrupt capable 31 PWM channels Built-in BLE radio 10 ADC channels with 14-bit precision with up to 2.67 million samples per second effective continuous, multi-slot sampling rate 2 channel differential ADC 2 UARTs 6 I²C buses 6 SPI buses 2/4/8-bit SPI bus PDM interface I²S Interface Secure 'Smart Card' interface Qwiic Connector

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The MotoPi is an extension-board to control and use up to 16 PWM-controlled 5 V servo motors. The board can be additional powered by a voltage between 4.8 V and 6 V so a perfect supply is always guaranteed and even larger projects can be powered. With the additional power supply and the integrated Analog-Digital-Converter, new possibilities can be reached. An additional power supply per motor is not required anymore because all connections (Voltage, Ground, Control) are directly connected to the board. The control and the programing can be directly done, as usual, on the Raspberry Pi. Specifications Special features 16 Channels, own clock generator, Inkl. Analog Digital Converter Input 1 Coaxial power connector 5.5 / 2.1 mm, 5 V / 6 A max Input 2 Screw terminal, 4.8-6 V / 6 A max Compatible with Raspberry Pi A+, B+, 2B, 3B Dimensions 65 x 56 x 24 mm Scope of supply Board, manual, fixing material

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The OKdo E1 is an ultra-low-cost Development Board based on the NXP LPC55S69JBD100 dual-core Arm Cortex-M33 microcontroller. The E1 board is perfect for Industrial IoT, building control and automation, consumer electronics, general embedded and secure applications. Features Processor with Arm TrustZone, Floating Point Unit (FPU) and Memory Protection Unit (MPU) CASPER Crypto co-processor to enable hardware acceleration for certain asymmetric cryptographic algorithms PowerQuad Hardware Accelerator for fixed and floating point DSP functions SRAM Physical Unclonable Function (PUF) for key generation, storage and reconstruction PRINCE module for real-time encryption and decryption of flash data AES-256 and SHA2 engines Up to Nine Flexcomm interfaces. Each Flexcomm interface can be selected by software to be a USART, SPI, I²C, and I²S interface USB 2.0 High-Speed Host/Device controller with on-chip PHY USB 2.0 Full-Speed Host/Device controller with on-chip PHY Up to 64 GPIOs Secure digital input/output (SD/MMC and SDIO) card interface Specifications LPC55S69JBD100 640kbyte flash microcontroller In-built CMSIS-DAP v1.0.7 debugger based on LPC11U35 Internal PLL support up to 100MHz operation, 16MHz can be mounted for full 150MHz operation. SRAM 320kB 32kHz crystal for real-time clock 4 user switches 3-colour LED User USB connector 2-off 16-way expansion connectors UART over USB virtual COM port

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LuckFox Pico Mini is a compact Linux micro development board based on the Rockchip RV1103 chip, providing a simple and efficient development platform for developers. It supports a variety of interfaces, including MIPI CSI, GPIO, UART, SPI, I²C, USB, etc., which is convenient for quick development and debugging. Features Single-core ARM Cortex-A7 32-bit core with integrated NEON and FPU Built-in Rockchip self-developed 4th generation NPU, features high computing precision and supports int, int8, and int16 hybrid quantization. The computing power of int8 is 0.5 TOPS, and up to 1.0 TOPS with int4 Built-in self-developed third-generation ISP3.2, supports 4-Megapixel, with multiple image enhancement and correction algorithms such as HDR, WDR, multi-level noise reduction, etc. Features powerful encoding performance, supports intelligent encoding mode and adaptive stream saving according to the scene, saves more than 50% bit rate of the conventional CBR mode so that the images from camera are high-definition with smaller size, double the storage space Built-in RISC-V MCU supports low power consumption and fast start-up, supports 250 ms fast picture capture and loading Al model library at the same time to realize face recognition "in one second" Built-in 16-bit DRAM DDR2, which is capable of sustaining demanding memory bandwidths Integrated with built-in POR, audio codec and MAC PHY Specifications Processor ARM Cortex-A7, single-core 32-bit CPU, 1.2 GHz, with NEON and FPU NPU Rockchip 4th-gen NPU, supports int4, int8, int16; up to 1.0 TOPS (int4) ISP Third-gen ISP3.2, up to 4 MP input at 30fps, HDR, WDR, noise reduction RAM 64 MB DDR2 Storage 128 MB SPI NAND Flash USB USB 2.0 Host/Device via Type-C Camera Interface MIPI CSI 2-lane GPIO Pins 17 GPIO pins Power Consumption Low power, RISC-V MCU for fast startup Dimensions 28 x 21 mm Downloads Wiki

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Use the right tool for the right job. These steel stakes are used to press the rivets on the PCB after holes have been drilled. They have been designed for optimum performance on the ink and ensure an electrical connection between the top and bottom layers of your PCB. Learn how to use them here.

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Pimoroni Pico LiPo is powered and programmable via USB-C and comes with 16 MB of QSPI (XiP) flash. With the Qwiic/STEMMA QT connector you can hook up a whole host of different sensors and breakouts, and a debug connector for if you want to do your programming using a SWD debugger. There is an on/off button and a BOOTSEL button, which can also be used as a user switch.Pimoroni Pico LiPo also has onboard LiPo/LiIon battery management – the inbuilt charging circuitry means charging your battery is as easy as plugging your Pimoroni Pico Lipo in via USB. Two indicator LEDs connected to the battery circuit keep you informed of on/off state and charging status and it's compatible with any of our LiPo, LiIon and high capacity LiPo batteries.Programmable with C++, MicroPython or CircuitPython, Pimoroni Pico LiPo is the perfect powerhouse for your portable projects.Features Powered by RP2040 Dual ARM Cortex M0+ running at up to 133 Mhz 264 kB of SRAM 16 MB of QSPI flash supporting XiP MCP73831 charger with 215 mA charging current (datasheet) XB6096I2S battery protector (datasheet) USB-C connector for power, programming, and data transfer 4 pin Qw-ST (Qwiic / STEMMA QT) connector 3 pin debug connector (JST-SH) 2-pole JST PH battery connector, with polarity marked on the board Switch for basic input (doubles up as DFU select on boot) Power button Power, charging and user LED indicators On-board 3V3 regulator (max regulator current output 600mA) Input voltage range 3 - 5.5 V Compatible with Raspberry Pi Pico add-ons Measurements: approx 53 x 21 x 8 mm (L x W x H, including connectors) Downloads CircuitPython Getting started with CircuitPython guide

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This flash memory allows you to store and read data externally via the SPI interface of your microcontroller. The control of the module is exactly the same as with a conventional SD card and is therefore particularly simple. The module is especially suitable for mobile setups, where normal SD cards could slip out of the SD card slot. Specifications Special feature 3 V and 5 V operation due to the integrated voltage converter Supply voltage Vcc 3-5 V Logic level Vcc Interface SPI Memory size 512 MB Clock frequency Up to 50 MHz Dimensions 18 x 22 x 12 mm Weight 3 g

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The AD584 4-ch Voltage Reference Module is designed to provide stable and accurate reference voltages of 2.5 V, 5 V, 7.5 V, and 10 V. It incorporates the AD584 integrated circuit, known for its high accuracy and stability. Features Multiple Output Voltages: The module can output four different reference voltages (2.5 V, 5 V, 7.5 V, and 10 V) accessible through a single port. Microcontroller-based Switching: An onboard microcontroller facilitates switching between the four voltage outputs, with LED indicators displaying the active selection. User-Friendly Operation: A single button allows for easy cycling through the available reference voltages. Transparent Housing: The module is encased in a transparent housing, offering protection while allowing users to view the internal components. Power Supply Options: It can be powered via a built-in lithium battery (not included) or through a 5 V DC input. A charging indicator provides status updates during charging. Output Interface: Equipped with 4mm banana sockets for secure and reliable connections. Included 1x AD584 4-ch Voltage Reference Module with Housing Downloads Datasheet

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The Raspberry Pi A+ Case has been designed to fit both the Pi 3 Model A+ and the Pi 1 Model A+. The high-quality ABS construction consists of two parts. The base features cut-outs to allow access to the microSD Card and the the HDMI, audio/video and USB ports, as well as the power connector.

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