English

Fus3D: Decoding Consolidated 3D Geometry from Feed-forward Geometry Transformer Latents

Computer Vision and Pattern Recognition 2026-03-30 v1

Abstract

We propose a feed-forward method for dense Signed Distance Field (SDF) regression from unstructured image collections in less than three seconds, without camera calibration or post-hoc fusion. Our key insight is that the intermediate feature space of pretrained multi-view feed-forward geometry transformers already encodes a powerful joint world representation; yet, existing pipelines discard it, routing features through per-view prediction heads before assembling 3D geometry post-hoc, which discards valuable completeness information and accumulates inaccuracies. We instead perform 3D extraction directly from geometry transformer features via learned volumetric extraction: voxelized canonical embeddings that progressively absorb multi-view geometry information through interleaved cross- and self-attention into a structured volumetric latent grid. A simple convolutional decoder then maps this grid to a dense SDF. We additionally propose a scalable, validity-aware supervision scheme directly using SDFs derived from depth maps or 3D assets, tackling practical issues like non-watertight meshes. Our approach yields complete and well-defined distance values across sparse- and dense-view settings and demonstrates geometrically plausible completions. Code and further material can be found at https://lorafib.github.io/fus3d.

Keywords

Cite

@article{arxiv.2603.25827,
  title  = {Fus3D: Decoding Consolidated 3D Geometry from Feed-forward Geometry Transformer Latents},
  author = {Laura Fink and Linus Franke and George Kopanas and Marc Stamminger and Peter Hedman},
  journal= {arXiv preprint arXiv:2603.25827},
  year   = {2026}
}
R2 v1 2026-07-01T11:39:49.102Z