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
OpenOcc: Open Vocabulary 3D Scene Reconstruction via Occupancy Representation
Haochen Jiang, Yueming Xu, Yihan Zeng, Hang Xu, Wei Zhang, Jianfeng Feng, Li Zhang
Combining Local and Global Perception for Autonomous Navigation on Nano-UAVs
Lorenzo Lamberti, Georg Rutishauser, Francesco Conti, Luca Benini
AGRNav: Efficient and Energy-Saving Autonomous Navigation for Air-Ground Robots in Occlusion-Prone Environments
Junming Wang, Zekai Sun, Xiuxian Guan, Tianxiang Shen, Zongyuan Zhang, Tianyang Duan, Dong Huang, Shixiong Zhao, Heming Cui