What question did this study set out to answer?

The aim is to design a power architecture for a Compound-Wing Unmanned VTOL to improve its hovering efficiency.

March 1, 2026Open Access

Design and Control of Range-Extender-Based Compound-Wing Unmanned VTOL

Key Points

The aim is to design a power architecture for a Compound-Wing Unmanned VTOL to improve its hovering efficiency.
Optimized layout structure of the traditional Compound-Wing Unmanned VTOL
Designed a high-power-density hybrid-power range-extender with an internal combustion engine
Developed an electronic control unit using a locally linearized state-space equation and LQR
Conducted simulation experiments, ground running tests, and flight tests
Enhanced hovering efficiency of the UAV compared to traditional designs
Verified performance of the power architecture through various tests
Demonstrated effective control through the developed ECU

Abstract

This paper proposes a power architecture for a Compound-Wing Unmanned VTOL to supply power during the hovering state. To enhance the hovering efficiency of the UAV while considering the cruising efficiency, the layout structure of a traditional Compound-Wing Unmanned VTOL is optimized. A high-power-density hybrid-power range-extender using an ICE (internal combustion engine) suitable for the Compound-Wing Unmanned VTOL is designed. The engine electronic control unit (ECU) suitable for the range-extender is presented by using a locally linearized state-space equation and LQR (Linear-Quadratic Regulator). Simulation experiments, ground running tests, and flight tests have been conducted to verify the performance of the Compound-Wing Unmanned VTOL and its power architecture.

Design and Control of Range-Extender-Based Compound-Wing Unmanned VTOL

Key Points

Abstract

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