Collision Avoidance
Collision avoidance research focuses on enabling safe and efficient navigation for multiple agents, such as robots, UAVs, and spacecraft, in dynamic environments. Current efforts concentrate on developing robust control strategies, often employing model predictive control (MPC) frameworks integrated with control barrier functions (CBFs) or reinforcement learning (RL) algorithms, sometimes enhanced by techniques like diffusion models or neural networks for improved perception and planning. These advancements are crucial for various applications, including autonomous driving, multi-robot coordination, and space operations, improving safety and efficiency in increasingly complex systems. The field is also exploring distributed control methods and human-robot collaboration to address challenges in communication limitations and shared autonomy.
Papers
Control Barrier Functions in Dynamic UAVs for Kinematic Obstacle Avoidance: A Collision Cone Approach
Manan Tayal, Rajpal Singh, Jishnu Keshavan, Shishir Kolathaya
Obstacle Avoidance in Dynamic Environments via Tunnel-following MPC with Adaptive Guiding Vector Fields
Albin Dahlin, Yiannis Karayiannidis