English

Event-based SLAM Benchmark for High-Speed Maneuvers

Robotics 2026-04-28 v1

Abstract

Event-based cameras are bio-inspired sensors with pixels that independently and asynchronously respond to brightness changes at microsecond resolution, offering the potential to handle visual tasks in high-speed maneuvering scenarios. Existing event-based approaches, although successful in mitigating motion blur caused by high-speed maneuvers, suffer from many limitations. Some of them highlight a success of pose tracking for a fronto-parallel fast shaking camera closed to the structure, while others assume pure (optionally aggressive) three-degree-of-freedom rotations. The former requires persistent local map visibility within the field of view (FOV), whereas the latter fails to generalize to six-degree-of-freedom (6-DoF) motions where both linear and angular velocities may be large. Consequently, current successes do not fully demonstrate that event-based state estimation under arbitrary aggressive maneuvers is a fully solved problem. To quantitatively assess the extent to which the potential of event cameras has been unlocked, we conduct a thorough analysis of state-of-the-art (SOTA) event-based visual odometry (VO)/visual-inertial odometry (VIO) methods and report shortcomings in current public datasets. Furthermore, we introduce a benchmarking framework for event-based state estimation, called EvSLAM, characterized by sufficient variation in data collection platforms, diverse extreme lighting scenarios, and a wide scope of challenging motion patterns under a clear and rigorous definition of high-speed maneuvers for mobile robots, along with a novel evaluation metric designed to fairly assess the operational limits of event-based solutions. This framework benchmarks state-of-the-art methods, yielding insights into optimal architectures and persistent challenges.

Keywords

Cite

@article{arxiv.2604.24033,
  title  = {Event-based SLAM Benchmark for High-Speed Maneuvers},
  author = {Sheng Zhong and Junkai Niu and Guillermo Gallego and Kaizhen Sun and Yang Yi and Zhiqiang Miao and Dewen Hu and Yaonan Wang and Davide Scaramuzza and Yi Zhou},
  journal= {arXiv preprint arXiv:2604.24033},
  year   = {2026}
}
R2 v1 2026-07-01T12:36:20.935Z