Motion Planning
Motion planning focuses on generating safe and efficient trajectories for robots and autonomous systems to navigate complex environments and achieve specified goals. Current research emphasizes improving the efficiency of sampling-based methods through techniques like message-passing Monte Carlo and leveraging vision-language models and reinforcement learning for higher-level task planning and decision-making in dynamic scenarios. These advancements are crucial for enabling robots to perform increasingly complex tasks in real-world settings, impacting fields such as robotics, autonomous driving, and multi-agent systems.
Papers
Optimization-Based Motion Planning for Autonomous Agricultural Vehicles Turning in Constrained Headlands
Chen Peng, Peng Wei, Zhenghao Fei, Yuankai Zhu, Stavros G. Vougioukas
A Model Predictive Path Integral Method for Fast, Proactive, and Uncertainty-Aware UAV Planning in Cluttered Environments
Jacob Higgins, Nicholas Mohammad, Nicola Bezzo
Learning Complex Motion Plans using Neural ODEs with Safety and Stability Guarantees
Farhad Nawaz, Tianyu Li, Nikolai Matni, Nadia Figueroa
Kinodynamic Motion Planning via Funnel Control for Underactuated Unmanned Surface Vehicles
Dženan Lapandić, Christos K. Verginis, Dimos V. Dimarogonas, Bo Wahlberg
Mobility Strategy of Multi-Limbed Climbing Robots for Asteroid Exploration
Warley F. R. Ribeiro, Kentaro Uno, Masazumi Imai, Koki Murase, Barış Can Yalçın, Matteo El Hariry, Miguel A. Olivares-Mendez, Kazuya Yoshida
Multi-Robot Motion Planning: A Learning-Based Artificial Potential Field Solution
Dengyu Zhang, Guobin Zhu, Qingrui Zhang