Customizable Perturbation Synthesis for Robust SLAM Benchmarking
Abstract
Robustness is a crucial factor for the successful deployment of robots in unstructured environments, particularly in the domain of Simultaneous Localization and Mapping (SLAM). Simulation-based benchmarks have emerged as a highly scalable approach for robustness evaluation compared to real-world data collection. However, crafting a challenging and controllable noisy world with diverse perturbations remains relatively under-explored. To this end, we propose a novel, customizable pipeline for noisy data synthesis, aimed at assessing the resilience of multi-modal SLAM models against various perturbations. This pipeline incorporates customizable hardware setups, software components, and perturbed environments. In particular, we introduce comprehensive perturbation taxonomy along with a perturbation composition toolbox, allowing the transformation of clean simulations into challenging noisy environments. Utilizing the pipeline, we instantiate the Robust-SLAM benchmark, which includes diverse perturbation types, to evaluate the risk tolerance of existing advanced multi-modal SLAM models. Our extensive analysis uncovers the susceptibilities of existing SLAM models to real-world disturbance, despite their demonstrated accuracy in standard benchmarks. Our perturbation synthesis toolbox, SLAM robustness evaluation pipeline, and Robust-SLAM benchmark will be made publicly available at https://github.com/Xiaohao-Xu/SLAM-under-Perturbation/.
Cite
@article{arxiv.2402.08125,
title = {Customizable Perturbation Synthesis for Robust SLAM Benchmarking},
author = {Xiaohao Xu and Tianyi Zhang and Sibo Wang and Xiang Li and Yongqi Chen and Ye Li and Bhiksha Raj and Matthew Johnson-Roberson and Xiaonan Huang},
journal= {arXiv preprint arXiv:2402.08125},
year = {2024}
}
Comments
40 pages