This Quadcopter Drone project kit is developed by Mechatron Robotics to train the students in drone technology. This drone is a quadrotor unmanned aerial vehicle (UAV), commonly referred to as a quadcopter. It has four rotors, arranged in an ‘X’ configuration, where each rotor provides thrust and control through variation in speed.
The drone's structure allows for stable vertical takeoff and landing, as well as precise control for outdoor applications. This kit provides a responsive brushless motor-powered drone controlled by an Arduino-based flight controller.
The drone will be capable of autonomous and manual flight. Using an Arduino flight controller, the system aims to provide a cost-effective yet flexible platform for learning, development, and customization of flight algorithms and sensor integration. Key features include real-time flight stability through sensors, the MPU6050 (IMU) barometer for precision control via PID tuning, and the ability to handle moderate payloads for extended flight durations.
Technical Specifications:
Arduino-based Flight Controller: The flight controller is custom-made by Mechatron Robotics using Arduino DIP-28 (Dual Inline Package) with 28 pins (ATMEGA 328PPU) + 13 DOF servo controllers.
Operating Voltage: 1.8V – 5.5V
Motors: 2200KV Brushless Motors
Electronic Speed Controllers (ESCs): Standard 30A BLDC ESC Electronic Speed Controller with Connector
Battery: 11.1V 2200mAh 30C 3S Lithium Polymer Battery Pack
Remote Control: 2.4GHz 6CH RC Transmitter & Receiver
Frame Size: 450 mm (measured diagonally from motor to motor).
Integrated PCB (Power Distribution Board): The frame includes a built-in PCB to simplify wiring. This allows for easy power distribution from a single battery to all four motors and ESCs without additional wires.
Quadcopter Drone Project kit with 6 CH 2.4GHz Tx Rx
This Quadcopter Drone project kit is developed by Mechatron Robotics to train the students in drone technology. This drone is a quadrotor unmanned aerial vehicle (UAV), commonly referred to as a quadcopter. It has four rotors, arranged in an ‘X’ configuration, where each rotor provides thrust and control through variation in speed.
The drone's structure allows for stable vertical takeoff and landing, as well as precise control for outdoor applications. This kit provides a responsive brushless motor-powered drone controlled by an Arduino-based flight controller.
The drone will be capable of autonomous and manual flight. Using an Arduino flight controller, the system aims to provide a cost-effective yet flexible platform for learning, development, and customization of flight algorithms and sensor integration. Key features include real-time flight stability through sensors, the MPU6050 (IMU) barometer for precision control via PID tuning, and the ability to handle moderate payloads for extended flight durations.
