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Autores principales: Pietrantoni, Maxime, Csurka, Gabriela, Humenberger, Martin, Sattler, Torsten
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2406.08463
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author Pietrantoni, Maxime
Csurka, Gabriela
Humenberger, Martin
Sattler, Torsten
author_facet Pietrantoni, Maxime
Csurka, Gabriela
Humenberger, Martin
Sattler, Torsten
contents Visual localization techniques rely upon some underlying scene representation to localize against. These representations can be explicit such as 3D SFM map or implicit, such as a neural network that learns to encode the scene. The former requires sparse feature extractors and matchers to build the scene representation. The latter might lack geometric grounding not capturing the 3D structure of the scene well enough. This paper proposes to jointly learn the scene representation along with a 3D dense feature field and a 2D feature extractor whose outputs are embedded in the same metric space. Through a contrastive framework we align this volumetric field with the image-based extractor and regularize the latter with a ranking loss from learned surface information. We learn the underlying geometry of the scene with an implicit field through volumetric rendering and design our feature field to leverage intermediate geometric information encoded in the implicit field. The resulting features are discriminative and robust to viewpoint change while maintaining rich encoded information. Visual localization is then achieved by aligning the image-based features and the rendered volumetric features. We show the effectiveness of our approach on real-world scenes, demonstrating that our approach outperforms prior and concurrent work on leveraging implicit scene representations for localization.
format Preprint
id arxiv_https___arxiv_org_abs_2406_08463
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Self-supervised Learning of Neural Implicit Feature Fields for Camera Pose Refinement
Pietrantoni, Maxime
Csurka, Gabriela
Humenberger, Martin
Sattler, Torsten
Computer Vision and Pattern Recognition
Visual localization techniques rely upon some underlying scene representation to localize against. These representations can be explicit such as 3D SFM map or implicit, such as a neural network that learns to encode the scene. The former requires sparse feature extractors and matchers to build the scene representation. The latter might lack geometric grounding not capturing the 3D structure of the scene well enough. This paper proposes to jointly learn the scene representation along with a 3D dense feature field and a 2D feature extractor whose outputs are embedded in the same metric space. Through a contrastive framework we align this volumetric field with the image-based extractor and regularize the latter with a ranking loss from learned surface information. We learn the underlying geometry of the scene with an implicit field through volumetric rendering and design our feature field to leverage intermediate geometric information encoded in the implicit field. The resulting features are discriminative and robust to viewpoint change while maintaining rich encoded information. Visual localization is then achieved by aligning the image-based features and the rendered volumetric features. We show the effectiveness of our approach on real-world scenes, demonstrating that our approach outperforms prior and concurrent work on leveraging implicit scene representations for localization.
title Self-supervised Learning of Neural Implicit Feature Fields for Camera Pose Refinement
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2406.08463