Ego Motion
Ego motion, the estimation and understanding of a system's own movement, is a crucial area of research in robotics and computer vision, aiming to enable accurate self-localization and scene understanding. Current research focuses on developing robust and efficient algorithms for ego-motion estimation using diverse sensor modalities (cameras, LiDAR, radar, IMUs), often incorporating techniques like deep learning (e.g., transformers, convolutional neural networks), spiking neural networks, and iterative closest point (ICP) algorithms. These advancements are significantly impacting fields like autonomous navigation, augmented reality, and assistive technologies by improving the accuracy and reliability of perception systems in dynamic environments.
Papers
NeuroVE: Brain-inspired Linear-Angular Velocity Estimation with Spiking Neural Networks
Xiao Li, Xieyuanli Chen, Ruibin Guo, Yujie Wu, Zongtan Zhou, Fangwen Yu, Huimin Lu
On the Benefits of Visual Stabilization for Frame- and Event-based Perception
Juan Pablo Rodriguez-Gomez, Jose Ramiro Martinez-de Dios, Anibal Ollero, Guillermo Gallego
EgoPet: Egomotion and Interaction Data from an Animal's Perspective
Amir Bar, Arya Bakhtiar, Danny Tran, Antonio Loquercio, Jathushan Rajasegaran, Yann LeCun, Amir Globerson, Trevor Darrell
Dynamic Ego-Velocity estimation Using Moving mmWave Radar: A Phase-Based Approach
Argha Sen, Soham Chakraborty, Soham Tripathy, Sandip Chakraborty