Flight Time Optimization and Modeling of a Hybrid Gasoline-Electric Multirotor Drone: An Experimental Study

Drones have evolved rapidly over the decades, but the limited flight time inhibits multirotor drones from performing long-duration tasks. Batteries that power drones are considered an inadequate power source due to their low energy density. As gasoline is an energy-dense source, combining an electric propulsion system with gasoline engines should be considered. This paper proposes a novel hybrid multirotor drone design using two gasoline engines to provide the majority of the lift force and four electric motors to stabilize the drone. These propulsion systems have been characterized and optimized to exploit their respective advantages, which reduce the total energy consumption rate and increase flight time. Simulation and experimental results show that the hybrid gas-electric multirotor drone can achieve more than three times the flight time of the fully electric drone.

Automated summary

This paper proposes a novel hybrid multirotor drone design that combines two gasoline engines and four electric motors, significantly extending flight time.