LangSplat: 3D Language Gaussian Splatting

Humans live in a 3D world and commonly use natural language to interact with a 3D scene. Modeling a 3D language field to support open-ended language queries in 3D has gained increasing attention recently. This paper introduces LangSplat, which constructs a 3D language field that enables precise and...

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Bibliographic Details
Published inProceedings (IEEE Computer Society Conference on Computer Vision and Pattern Recognition. Online) pp. 20051 - 20060
Main Authors Qin, Minghan, Li, Wanhua, Zhou, Jiawei, Wang, Haoqian, Pfister, Hanspeter
Format Conference Proceeding
LanguageEnglish
Published IEEE 16.06.2024
Subjects
3D representation
Computer vision
Gaussian Splatting
Natural languages
Neural radiance field
open-vocabulary
Rendering (computer graphics)
semantic segmentation
Semantics
Solid modeling
Three-dimensional displays
Online AccessGet full text
ISSN1063-6919
DOI10.1109/CVPR52733.2024.01895

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Summary:Humans live in a 3D world and commonly use natural language to interact with a 3D scene. Modeling a 3D language field to support open-ended language queries in 3D has gained increasing attention recently. This paper introduces LangSplat, which constructs a 3D language field that enables precise and efficient open-vocabulary querying within 3D spaces. Unlike existing methods that ground CLIP language embeddings in a NeRF model, LangSplat advances the field by utilizing a collection of 3D Gaussians, each encoding language features distilled from CLIP, to represent the language field. By employing a tile-based splatting technique for rendering language features, we circumvent the costly rendering process inherent in NeRF. Instead of directly learning CLIP embeddings, LangSplat first trains a scene-wise language autoencoder and then learns language features on the scene-specific latent space, thereby alleviating substantial memory demands imposed by explicit modeling. Existing methods struggle with imprecise and vague 3D language fields, which fail to discern clear boundaries between objects. We delve into this issue and propose to learn hierarchical semantics using SAM, thereby eliminating the need for extensively querying the language field across various scales and the regularization of DINO features. Extensive experimental results show that LangSplat significantly outperforms the previous state-of-the-art method LERF by a large margin. Notably, LangSplat is extremely efficient, achieving a 199 x speedup compared to LERF at the resolution of 1440 x 1080. We strongly recommend readers to check out our video results at https://langsplat.github.io/
ISSN:1063-6919
DOI:10.1109/CVPR52733.2024.01895