Simultaneous Localization and Mapping
Simultaneous Localization and Mapping (SLAM) is a fundamental robotics problem aiming to build a map of an unknown environment while simultaneously tracking the robot's location within that map. Current research emphasizes improving SLAM's robustness and efficiency across diverse sensor modalities (LiDAR, cameras, IMUs) and challenging environments, often employing techniques like graph-based optimization, neural implicit representations (e.g., Gaussian splatting, NeRFs), and deep learning for feature extraction and loop closure detection. Advances in SLAM are crucial for enabling autonomous navigation in various applications, from autonomous vehicles and robots in industrial settings to medical procedures and exploration of unstructured environments.
Papers
Hyperion -- A fast, versatile symbolic Gaussian Belief Propagation framework for Continuous-Time SLAM
David Hug, Ignacio Alzugaray, Margarita Chli
A Neurosymbolic Approach to Adaptive Feature Extraction in SLAM
Yasra Chandio, Momin A. Khan, Khotso Selialia, Luis Garcia, Joseph DeGol, Fatima M. Anwar
Masked Video and Body-worn IMU Autoencoder for Egocentric Action Recognition
Mingfang Zhang, Yifei Huang, Ruicong Liu, Yoichi Sato