Autonomous Navigation
Autonomous navigation research aims to enable robots and vehicles to navigate complex environments without human intervention, focusing on safe and efficient path planning and execution. Current efforts concentrate on improving perception through sensor fusion (e.g., LiDAR, cameras, sonar) and leveraging machine learning techniques, particularly deep reinforcement learning and neural networks, for decision-making and control, often incorporating prior maps or learned models of environment dynamics. This field is crucial for advancing robotics, autonomous driving, and space exploration, with applications ranging from warehouse logistics and agricultural automation to underwater exploration and planetary landing.
Papers
Framework for Robust Localization of UUVs and Mapping of Net Pens
David Botta, Luca Ebner, Andrej Studer, Victor Reijgwart, Roland Siegwart, Eleni Kelasidi
Hierarchical end-to-end autonomous navigation through few-shot waypoint detection
Amin Ghafourian, Zhongying CuiZhu, Debo Shi, Ian Chuang, Francois Charette, Rithik Sachdeva, Iman Soltani
Learning a Terrain- and Robot-Aware Dynamics Model for Autonomous Mobile Robot Navigation
Jan Achterhold, Suresh Guttikonda, Jens U. Kreber, Haolong Li, Joerg Stueckler
Autonomous Navigation in Ice-Covered Waters with Learned Predictions on Ship-Ice Interactions
Ninghan Zhong, Alessandro Potenza, Stephen L. Smith
High performance Lunar landing simulations
Jérémy Lebreton, Roland Brochard, Nicolas Ollagnier, Matthieu Baudry, Adrien Hadj Salah, Grégory Jonniaux, Keyvan Kanani, Matthieu Le Goff, Aurore Masson
Online Diffusion-Based 3D Occupancy Prediction at the Frontier with Probabilistic Map Reconciliation
Alec Reed, Lorin Achey, Brendan Crowe, Bradley Hayes, Christoffer Heckman
Digital Twins Meet the Koopman Operator: Data-Driven Learning for Robust Autonomy
Chinmay Vilas Samak, Tanmay Vilas Samak, Ajinkya Joglekar, Umesh Vaidya, Venkat Krovi
Aligning Robot Navigation Behaviors with Human Intentions and Preferences
Haresh Karnan