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Autori principali: Li, Lei, Peng, Songyou, Yu, Zehao, Liu, Shaohui, Pautrat, Rémi, Yin, Xiaochuan, Pollefeys, Marc
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2405.19295
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author Li, Lei
Peng, Songyou
Yu, Zehao
Liu, Shaohui
Pautrat, Rémi
Yin, Xiaochuan
Pollefeys, Marc
author_facet Li, Lei
Peng, Songyou
Yu, Zehao
Liu, Shaohui
Pautrat, Rémi
Yin, Xiaochuan
Pollefeys, Marc
contents Real-world objects and environments are predominantly composed of edge features, including straight lines and curves. Such edges are crucial elements for various applications, such as CAD modeling, surface meshing, lane mapping, etc. However, existing traditional methods only prioritize lines over curves for simplicity in geometric modeling. To this end, we introduce EMAP, a new method for learning 3D edge representations with a focus on both lines and curves. Our method implicitly encodes 3D edge distance and direction in Unsigned Distance Functions (UDF) from multi-view edge maps. On top of this neural representation, we propose an edge extraction algorithm that robustly abstracts parametric 3D edges from the inferred edge points and their directions. Comprehensive evaluations demonstrate that our method achieves better 3D edge reconstruction on multiple challenging datasets. We further show that our learned UDF field enhances neural surface reconstruction by capturing more details.
format Preprint
id arxiv_https___arxiv_org_abs_2405_19295
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle 3D Neural Edge Reconstruction
Li, Lei
Peng, Songyou
Yu, Zehao
Liu, Shaohui
Pautrat, Rémi
Yin, Xiaochuan
Pollefeys, Marc
Computer Vision and Pattern Recognition
Real-world objects and environments are predominantly composed of edge features, including straight lines and curves. Such edges are crucial elements for various applications, such as CAD modeling, surface meshing, lane mapping, etc. However, existing traditional methods only prioritize lines over curves for simplicity in geometric modeling. To this end, we introduce EMAP, a new method for learning 3D edge representations with a focus on both lines and curves. Our method implicitly encodes 3D edge distance and direction in Unsigned Distance Functions (UDF) from multi-view edge maps. On top of this neural representation, we propose an edge extraction algorithm that robustly abstracts parametric 3D edges from the inferred edge points and their directions. Comprehensive evaluations demonstrate that our method achieves better 3D edge reconstruction on multiple challenging datasets. We further show that our learned UDF field enhances neural surface reconstruction by capturing more details.
title 3D Neural Edge Reconstruction
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2405.19295