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Autores principales: Ferede, Robin, De Wagter, Christophe, Izzo, Dario, de Croon, Guido C. H. E.
Formato: Preprint
Publicado: 2023
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Acceso en línea:https://arxiv.org/abs/2311.16948
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author Ferede, Robin
De Wagter, Christophe
Izzo, Dario
de Croon, Guido C. H. E.
author_facet Ferede, Robin
De Wagter, Christophe
Izzo, Dario
de Croon, Guido C. H. E.
contents Aggressive time-optimal control of quadcopters poses a significant challenge in the field of robotics. The state-of-the-art approach leverages reinforcement learning (RL) to train optimal neural policies. However, a critical hurdle is the sim-to-real gap, often addressed by employing a robust inner loop controller -an abstraction that, in theory, constrains the optimality of the trained controller, necessitating margins to counter potential disturbances. In contrast, our novel approach introduces high-speed quadcopter control using end-to-end RL (E2E) that gives direct motor commands. To bridge the reality gap, we incorporate a learned residual model and an adaptive method that can compensate for modeling errors in thrust and moments. We compare our E2E approach against a state-of-the-art network that commands thrust and body rates to an INDI inner loop controller, both in simulated and real-world flight. E2E showcases a significant 1.39-second advantage in simulation and a 0.17-second edge in real-world testing, highlighting end-to-end reinforcement learning's potential. The performance drop observed from simulation to reality shows potential for further improvement, including refining strategies to address the reality gap or exploring offline reinforcement learning with real flight data.
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publishDate 2023
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spellingShingle End-to-end Reinforcement Learning for Time-Optimal Quadcopter Flight
Ferede, Robin
De Wagter, Christophe
Izzo, Dario
de Croon, Guido C. H. E.
Robotics
Aggressive time-optimal control of quadcopters poses a significant challenge in the field of robotics. The state-of-the-art approach leverages reinforcement learning (RL) to train optimal neural policies. However, a critical hurdle is the sim-to-real gap, often addressed by employing a robust inner loop controller -an abstraction that, in theory, constrains the optimality of the trained controller, necessitating margins to counter potential disturbances. In contrast, our novel approach introduces high-speed quadcopter control using end-to-end RL (E2E) that gives direct motor commands. To bridge the reality gap, we incorporate a learned residual model and an adaptive method that can compensate for modeling errors in thrust and moments. We compare our E2E approach against a state-of-the-art network that commands thrust and body rates to an INDI inner loop controller, both in simulated and real-world flight. E2E showcases a significant 1.39-second advantage in simulation and a 0.17-second edge in real-world testing, highlighting end-to-end reinforcement learning's potential. The performance drop observed from simulation to reality shows potential for further improvement, including refining strategies to address the reality gap or exploring offline reinforcement learning with real flight data.
title End-to-end Reinforcement Learning for Time-Optimal Quadcopter Flight
topic Robotics
url https://arxiv.org/abs/2311.16948