Modeling and Measuring Redundancy in Multisource Multimodal Data for Autonomous Driving
Abstract
Next-generation autonomous vehicles (AVs) rely on large volumes of multisource and multimodal () data to support real-time decision-making. In practice, data quality (DQ) varies across sources and modalities due to environmental conditions and sensor limitations, yet AV research has largely prioritized algorithm design over DQ analysis. This work focuses on redundancy as a fundamental but underexplored DQ issue in AV datasets. Using the nuScenes and Argoverse 2 (AV2) datasets, we model and measure redundancy in multisource camera data and multimodal image-LiDAR data, and evaluate how removing redundant labels affects the YOLOv8 object detection task. Experimental results show that selectively removing redundant multisource image object labels from cameras with shared fields of view improves detection. In nuScenes, mAP gains from to , to , and from to , on three representative overlap regions, while detection on other overlapping camera pairs remains at the baseline even under stronger pruning. In AV2, - of labels are removed, and mAP stays near the baseline. Multimodal analysis also reveals substantial redundancy between image and LiDAR data. These findings demonstrate that redundancy is a measurable and actionable DQ factor with direct implications for AV performance. This work highlights the role of redundancy as a data quality factor in AV perception and motivates a data-centric perspective for evaluating and improving AV datasets. Code, data, and implementation details are publicly available at: https://github.com/yhZHOU515/RedundancyAD
Cite
@article{arxiv.2603.06544,
title = {Modeling and Measuring Redundancy in Multisource Multimodal Data for Autonomous Driving},
author = {Yuhan Zhou and Mehri Sattari and Haihua Chen and Kewei Sha},
journal= {arXiv preprint arXiv:2603.06544},
year = {2026}
}
Comments
This paper has been accepted by the Fourth IEEE International Conference on Mobility: Operations, Services, and Technologies (MOST) 2026