Robust Locomotion
Robust locomotion research aims to enable robots to move reliably and efficiently across diverse and unpredictable terrains, mirroring the adaptability of animals. Current efforts focus on developing controllers using reinforcement learning, model predictive control, and hybrid approaches that integrate proprioceptive and exteroceptive sensing, often incorporating advanced architectures like neural networks and vision-language models. These advancements are crucial for expanding the capabilities of robots in challenging environments, impacting fields such as search and rescue, logistics, and exploration.
Papers
Deep-Learning Control of Lower-Limb Exoskeletons via simplified Therapist Input
Lorenzo Vianello, Clément Lhoste, Emek Barış Küçüktabak, Matthew Short, Levi Hargrove, Jose L. Pons
Mobile-TeleVision: Predictive Motion Priors for Humanoid Whole-Body Control
Chenhao Lu, Xuxin Cheng, Jialong Li, Shiqi Yang, Mazeyu Ji, Chengjing Yuan, Ge Yang, Sha Yi, Xiaolong Wang
Real-Time Whole-Body Control of Legged Robots with Model-Predictive Path Integral Control
Juan Alvarez-Padilla, John Z. Zhang, Sofia Kwok, John M. Dolan, Zachary Manchester
Safety-critical Locomotion of Biped Robots in Infeasible Paths: Overcoming Obstacles during Navigation toward Destination
Jaemin Lee, Min Dai, Jeeseop Kim, Aaron D. Ames