Towards Autonomous Lunar Resource Excavation via Deep Reinforcement Learning
Towards Autonomous Lunar Resource Excavation via Deep Reinforcement Learning
- Neue Suche nach: J. M. Cloud
- Neue Suche nach: R. J. Nieves
- Neue Suche nach: A. K. Duke
- Neue Suche nach: T. J. Muller
- Neue Suche nach: N. A. Janmohamed
- Neue Suche nach: B. C. Buckles
- Neue Suche nach: M. A. Dupuis
- Neue Suche nach: J. M. Cloud
- Neue Suche nach: R. J. Nieves
- Neue Suche nach: A. K. Duke
- Neue Suche nach: T. J. Muller
- Neue Suche nach: N. A. Janmohamed
- Neue Suche nach: B. C. Buckles
- Neue Suche nach: M. A. Dupuis
To support sustainable infrastructure on the Moon, NASA needs to leverage lunar resources for in-situ processing and construction. NASA’s Regolith Advanced Surface Systems Operations Robot (RASSOR) is principally designed to mine and deliver regolith for these tasks. To reliably perform these operations on the lunar surface, RASSOR's sensors and control systems need to be robust and maximize information extracted from a reduced sensor payload. Herein, we present our findings from the Intelligent Capabilities Enhanced RASSOR project. We created reduced-order simulation environments in which we applied reinforcement learning algorithms to learn autonomous trenching controllers and produced state estimation architectures. We developed two simulations: a 2D excavation simulation used to facilitate parameter selection, and a 3D simulation developed using a game physics engine to simulate simplified soil interactions and incorporate robotic agents parameterized by dynamic models. Within these simulations, we learned autonomous excavation routines that exceed excavation efficiency measures as compared against RASSOR's existing control and teleoperation-based methods.
Dokumentinformationen
Towards Autonomous Lunar Resource Excavation via Deep Reinforcement Learning
2021
22 pages
Report
Keine Angabe
Englisch