Fault Tolerance of RPM-Controlled Hexacopters with Reverse-Enabled Rotors

SM-2026-VLADA-5213

1/27/2026

Authors
Abstract
Content

RPM-controlled hexacopters offer mechanical simplicity and inherent redundancy, but are unable to re-trim under all failure cases in forward flight. This paper investigates the use of reverse-enabled rotors as a means of expanding the attainable trim envelope and improving fault tolerance in RPM-controlled hexacopters. Isolated rotor experiments are conducted to characterize thrust and torque behavior under forward and reverse rotation, providing validation data for aerodynamic modeling. A blade-element-based model implemented in the Rensselaer Multicopter Analysis Code (RMAC) is then used to perform comprehensive trim analyses for a 1200-lb-class hexacopter in hover and in cruise at the best-range speed of 65 kts. Post-failure trim solutions are evaluated for four configurations, including edge-first and vertex-first orientations with different rotor spin directions. Results show that enabling reverse rotation allows trim recovery for all single-rotor failure cases in cruise, including aft-rotor failures that are not trimmable with conventional RPM-controlled rotors. A systematic comparison of peak rotor torque, peak rotor power, and total aircraft power reveals that failure severity is governed primarily by yaw moment deficits arising from the combined loss of hub torque and aerodynamic drag. Among the configurations examined, the edge-first configuration with a counter-clockwise spinning rotor 1 exhibits the lowest rotor torque and rotor power requirements, post-failure.

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Pages
16
Citation
Fong, W. and Gandhi, F., "Fault Tolerance of RPM-Controlled Hexacopters with Reverse-Enabled Rotors," Vertical Lift Aircraft Design and Aeromechanics Specialists Conference, San Jose, California, Jan 2026, San Jose, California, January 27, 2026, .
Additional Details
Publisher
Published
Jan 27
Product Code
SM-2026-VLADA-5213
Content Type
Technical Paper
Language
English