A top of the line Pirate-brand RP2040-powered microcontroller with lots of flash memory, USB-C, STEMMA QT/Qwiic and debug connectors... and built in LiPo charging!
We adore the versatility and value of Raspberry Pi Pico but since its release we've been hankering for a souped up RP2040 board with all the extras baked in. With Pimoroni Pico boards, we've tried to cram in as much extra functionality as we possibly can whilst keeping to the Pico footprint to maintain compatibility with existing Pico addons.
Pimoroni Pico LiPo is powered and programmable via USB-C and comes with a mighty 16MB of QSPI (XiP) flash on board to take on the chunkiest of projects (we'll also have a 4MB version available soon). We've made it super easy to connect to things solderlessly too - there's a Qwiic/STEMMA QT connector so 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. Because we love buttons at Pirate HQ, there's 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. There's two indicator LEDs connected to the battery circuit to 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.
Safety note! You should only use Pimoroni Pico LiPo with LiPo or LiIon batteries, and you should make sure that any project involving LiPos is sufficiently protected from being dented, bent, punctured or crushed.
Features
- Powered by RP2040
- Dual ARM Cortex M0+ running at up to 133Mhz
- 264kB of SRAM
- 4MB/16MB of QSPI flash supporting XiP
- MCP73831 charger with 215mA 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 3V - 5.5V
- Compatible with Raspberry Pi Pico add-ons
- Measurements: approx 53mm x 21mm x 8mm (L x W x H, including connectors)
Batteries, cables and headers are not included - check out the extras tab!
Getting Started
Pimoroni Pico boards are firmware agnostic! You can program them with C/C++ or MicroPython in the same way as you would a Raspberry Pi Pico. You can find (lots) more information on how to do that (as well as download links for the firmware/SDK) on the RP2040 landing page.
You can also use CircuitPython on your Pimoroni Pico LiPo! CircuitPython is an easy to use, well-established ecosystem with lots of example code and drivers for interfacing with different kinds of hardware. Click here to download the CircuitPython firmware for Pimoroni Pico LiPo and click here for a getting started guide.
Notes
- The power button can also be used as a reset button, yay! Just double press it to cut and reinstate the power whilst holding down the BOOTSEL button on the Pimoroni Pico LiPo to get into bootloader mode, with no plugging and unplugging of cables required.
About RP2040
Raspberry Pi's RP2040 microcontroller is a dual core ARM Cortex M0+ running at up to 133Mhz. It bundles in 264kB of SRAM, 30 multifunction GPIO pins (including a four channel 12-bit ADC), a heap of standard peripherals (I2C, SPI, UART, PWM, clocks, etc), and USB support.
One very exciting feature of RP2040 is the programmable IOs which allow you to execute custom programs that can manipulate GPIO pins and transfer data between peripherals - they can offload tasks that require high data transfer rates or precise timing that traditionally would have required a lot of heavy lifting from the CPU.