GASP: Unifying Geometric and Semantic Self-Supervised Pretraining for Autonomous Driving
Paper in proceeding, 2026

Self-supervised pre-training based on next-token prediction has enabled large language models to capture the underlying structure of text, and has led to unprecedented performance on a large array of tasks when applied at scale.
Similarly, autonomous driving generates vast amounts of spatiotemporal data, alluding to the possibility of harnessing scale to learn the underlying geometric and semantic structure of the environment and its evolution over time.
In this direction, we propose a geometric and semantic self-supervised pre-training method, GASP, that learns a unified representation by predicting, at any queried future point in spacetime, (1) general occupancy, capturing the evolving structure of the 3D scene; (2) ego occupancy, modeling the ego vehicle path through the environment; and (3) distilled high-level features from a vision foundation model.
By modeling geometric and semantic 4D occupancy fields instead of raw sensor measurements, the model learns a structured, generalizable representation of the environment and its evolution through time.
We validate GASP on multiple autonomous driving benchmarks, demonstrating significant improvements in semantic occupancy forecasting, online mapping, and ego trajectory prediction.
Our results demonstrate that continuous 4D geometric and semantic occupancy prediction provides a scalable and effective pre-training paradigm for autonomous driving.

Author

William Ljungbergh

Adam Lilja

Chalmers, Electrical Engineering, Signal Processing and Biomedical Engineering

Adam Tonderski

Zenseact AB

Arvid Laveno Ling

Chalmers, Electrical Engineering, Systems and control

Carl Lindström

Chalmers, Electrical Engineering, Signal Processing and Biomedical Engineering

Willem Verbeke

Zenseact AB

Junsheng Fu

Zenseact AB

Christoffer Petersson

Chalmers, Mathematical Sciences, Algebra and geometry

Lars Hammarstrand

Chalmers, Electrical Engineering, Signal Processing and Biomedical Engineering

Michael Felsberg

Linköping University

Proceedings - 2025 IEEE Winter Conference on Applications of Computer Vision, WACV 2025

Proceedings of the IEEE/CVF Winter Conference on Applications of Computer Vision
Tuscon, USA,

Subject Categories (SSIF 2025)

Robotics and automation

Computer graphics and computer vision

Computer Sciences

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Latest update

6/22/2026