Mh-fc V2.2 Here

Waits for that beam to bounce off an object and return.

The curriculum is broken down into several key phases:

Powered by a 32-bit ARM Cortex-M core (frequently utilizing STM32 architecture), enabling high-frequency PID loop calculations and real-time telemetry processing.

Served as the hardware platform for teaching sensor interfacing (IMU, GNSS), motor control (PWM), and radio telemetry. Development Environment: Typically programmed using STM32CubeIDE and configured via STM32CubeMX Hardware Setup & Components Mh-fc V2.2

What do you have available? Share public link

This public link is valid for 7 days and shares a thread, including any personal information you added. This link or copies made by others cannot be deleted. If you share with third parties, their policies apply. Can’t copy the link right now. Try again later.

Have you already migrated to Mh-fc V2.2? Share your performance benchmarks and custom use cases in the comments below. For more technical deep dives, subscribe to our monthly Embedded Systems newsletter. Waits for that beam to bounce off an object and return

Designed for easy interfacing with standard drone parts: iBus/SBUS/PPM Radio Receiver . GPS Modules (M8N/M9N) for positional hold. Barometer (LPS22HH) for altitude holding.

Integrated LPS22HH sensor for altitude sensing via SPI interface.

2cm to 30cm (adjustable via onboard potentiometer). Detection Angle: 35°. If you share with third parties, their policies apply

The digital output pin connected to a GPIO pin on your microcontroller.

“Cobalt, route med-drone to Perez. Shift fire team alpha to cover his retreat.”

Supports NEO M8N GPS and FS-iA6B receivers using the i-Bus protocol. SPI/I2C: Interfaces for various onboard sensors and EEPROM.

Implementing the math required to stabilize a quadcopter in 3D space.