English

Learnability-Driven Submodular Optimization for Active Roadside 3D Detection

Computer Vision and Pattern Recognition 2026-01-06 v1

Abstract

Roadside perception datasets are typically constructed via cooperative labeling between synchronized vehicle and roadside frame pairs. However, real deployment often requires annotation of roadside-only data due to hardware and privacy constraints. Even human experts struggle to produce accurate labels without vehicle-side data (image, LIDAR), which not only increases annotation difficulty and cost, but also reveals a fundamental learnability problem: many roadside-only scenes contain distant, blurred, or occluded objects whose 3D properties are ambiguous from a single view and can only be reliably annotated by cross-checking paired vehicle--roadside frames. We refer to such cases as inherently ambiguous samples. To reduce wasted annotation effort on inherently ambiguous samples while still obtaining high-performing models, we turn to active learning. This work focuses on active learning for roadside monocular 3D object detection and proposes a learnability-driven framework that selects scenes which are both informative and reliably labelable, suppressing inherently ambiguous samples while ensuring coverage. Experiments demonstrate that our method, LH3D, achieves 86.06%, 67.32%, and 78.67% of full-performance for vehicles, pedestrians, and cyclists respectively, using only 25% of the annotation budget on DAIR-V2X-I, significantly outperforming uncertainty-based baselines. This confirms that learnability, not uncertainty, matters for roadside 3D perception.

Keywords

Cite

@article{arxiv.2601.01695,
  title  = {Learnability-Driven Submodular Optimization for Active Roadside 3D Detection},
  author = {Ruiyu Mao and Baoming Zhang and Nicholas Ruozzi and Yunhui Guo},
  journal= {arXiv preprint arXiv:2601.01695},
  year   = {2026}
}

Comments

10 pages, 7 figures. Submitted to CVPR 2026

R2 v1 2026-07-01T08:50:11.487Z