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Autori principali: Li, Yan, Yang, Ze, Tateno, Keisuke, Tombari, Federico, Zhao, Liang, Lee, Gim Hee
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2508.04335
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author Li, Yan
Yang, Ze
Tateno, Keisuke
Tombari, Federico
Zhao, Liang
Lee, Gim Hee
author_facet Li, Yan
Yang, Ze
Tateno, Keisuke
Tombari, Federico
Zhao, Liang
Lee, Gim Hee
contents Minimal parametrization of 3D lines plays a critical role in camera localization and structural mapping. Existing representations in robotics and computer vision predominantly handle independent lines, overlooking structural regularities such as sets of parallel lines that are pervasive in man-made environments. This paper introduces \textbf{RiemanLine}, a unified minimal representation for 3D lines formulated on Riemannian manifolds that jointly accommodates both individual lines and parallel-line groups. Our key idea is to decouple each line landmark into global and local components: a shared vanishing direction optimized on the unit sphere $\mathcal{S}^2$, and scaled normal vectors constrained on orthogonal subspaces, enabling compact encoding of structural regularities. For $n$ parallel lines, the proposed representation reduces the parameter space from $4n$ (orthonormal form) to $2n+2$, naturally embedding parallelism without explicit constraints. We further integrate this parameterization into a factor graph framework, allowing global direction alignment and local reprojection optimization within a unified manifold-based bundle adjustment. Extensive experiments on ICL-NUIM, TartanAir, and synthetic benchmarks demonstrate that our method achieves significantly more accurate pose estimation and line reconstruction, while reducing parameter dimensionality and improving convergence stability.
format Preprint
id arxiv_https___arxiv_org_abs_2508_04335
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle RiemanLine: Riemannian Manifold Representation of 3D Lines for Factor Graph Optimization
Li, Yan
Yang, Ze
Tateno, Keisuke
Tombari, Federico
Zhao, Liang
Lee, Gim Hee
Computer Vision and Pattern Recognition
Robotics
Minimal parametrization of 3D lines plays a critical role in camera localization and structural mapping. Existing representations in robotics and computer vision predominantly handle independent lines, overlooking structural regularities such as sets of parallel lines that are pervasive in man-made environments. This paper introduces \textbf{RiemanLine}, a unified minimal representation for 3D lines formulated on Riemannian manifolds that jointly accommodates both individual lines and parallel-line groups. Our key idea is to decouple each line landmark into global and local components: a shared vanishing direction optimized on the unit sphere $\mathcal{S}^2$, and scaled normal vectors constrained on orthogonal subspaces, enabling compact encoding of structural regularities. For $n$ parallel lines, the proposed representation reduces the parameter space from $4n$ (orthonormal form) to $2n+2$, naturally embedding parallelism without explicit constraints. We further integrate this parameterization into a factor graph framework, allowing global direction alignment and local reprojection optimization within a unified manifold-based bundle adjustment. Extensive experiments on ICL-NUIM, TartanAir, and synthetic benchmarks demonstrate that our method achieves significantly more accurate pose estimation and line reconstruction, while reducing parameter dimensionality and improving convergence stability.
title RiemanLine: Riemannian Manifold Representation of 3D Lines for Factor Graph Optimization
topic Computer Vision and Pattern Recognition
Robotics
url https://arxiv.org/abs/2508.04335