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
AMSwarm: An Alternating Minimization Approach for Safe Motion Planning of Quadrotor Swarms in Cluttered Environments
Vivek K. Adajania, Siqi Zhou, Arun Kumar Singh, Angela P. Schoellig
Monte-Carlo Tree Search with Prioritized Node Expansion for Multi-Goal Task Planning
Kai Pfeiffer, Leonardo Edgar, Quang-Cuong Pham
Efficient Skill Acquisition for Complex Manipulation Tasks in Obstructed Environments
Jun Yamada, Jack Collins, Ingmar Posner
Leveraging Scene Embeddings for Gradient-Based Motion Planning in Latent Space
Jun Yamada, Chia-Man Hung, Jack Collins, Ioannis Havoutis, Ingmar Posner
Graph-based View Motion Planning for Fruit Detection
Tobias Zaenker, Julius Rückin, Rohit Menon, Marija Popović, Maren Bennewitz
ROG-Map: An Efficient Robocentric Occupancy Grid Map for Large-scene and High-resolution LiDAR-based Motion Planning
Yunfan Ren, Yixi Cai, Fangcheng Zhu, Siqi Liang, Fu Zhang
Paramater Optimization for Manipulator Motion Planning using a Novel Benchmark Set
Carl Gaebert, Sascha Kaden, Benjamin Fischer, Ulrike Thomas
A Supervisory Learning Control Framework for Autonomous & Real-time Task Planning for an Underactuated Cooperative Robotic task
Sander De Witte, Tom Lefebvre, Thijs Van Hauwermeiren, Guillaume Crevecoeur
A Novel Vector-Field-Based Motion Planning Algorithm for 3D Nonholonomic Robots
Xiaodong He, Weijia Yao, Zhiyong Sun, Zhongkui Li