Nonlinear MPC with Motor Failure Identification and Recovery for Safe and Aggressive Multicopter Flight
This addresses safety and reliability for multicopters in cluttered environments, representing an incremental improvement with specific failure handling.
The paper tackles the problem of safe and aggressive multicopter flight under motor failures by developing a nonlinear MPC with motor failure identification and recovery, achieving safe operation even after motor loss as verified in flight experiments.
Safe and precise reference tracking is a crucial characteristic of MAVs that have to operate under the influence of external disturbances in cluttered environments. In this paper, we present a NMPC that exploits the fully physics based non-linear dynamics of the system. We furthermore show how the moment and thrust control inputs can be transformed into feasible actuator commands. In order to guarantee safe operation despite potential loss of a motor under which we show our system keeps operating safely, we developed an EKF based motor failure identification algorithm. We verify the effectiveness of the developed pipeline in flight experiments with and without motor failures.