Video Prediction of Dynamic Physical Simulations With Pixel-Space Spatiotemporal Transformers
Author(s) -
Dean L. Slack,
G. Thomas Hudson,
Thomas Winterbottom,
Noura Al Moubayed
Publication year - 2025
Publication title -
ieee transactions on neural networks and learning systems
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.882
H-Index - 212
eISSN - 2162-2388
pISSN - 2162-237X
DOI - 10.1109/tnnls.2025.3585949
Subject(s) - computing and processing , communication, networking and broadcast technologies , components, circuits, devices and systems , general topics for engineers
Inspired by the performance and scalability of autoregressive large language models (LLMs), transformer-based models have seen recent success in the visual domain. This study investigates a transformer adaptation for video prediction with a simple end-to-end approach, comparing various spatiotemporal self-attention layouts. Focusing on causal modeling of physical simulations over time; a common shortcoming of existing video-generative approaches, we attempt to isolate spatiotemporal reasoning via physical object tracking metrics and unsupervised training on physical simulation datasets. We introduce a simple yet effective pure transformer model for autoregressive video prediction, utilizing continuous pixel-space representations for video prediction. Without the need for complex training strategies or latent feature-learning components, our approach significantly extends the time horizon for physically accurate predictions by up to 50% when compared with existing latent-space approaches, while maintaining comparable performance on common video quality metrics. In addition, we conduct interpretability experiments to identify network regions that encode information useful to perform accurate estimations of PDE simulation parameters via probing models, and find that this generalizes to the estimation of out-of-distribution simulation parameters. This work serves as a platform for further attention-based spatiotemporal modeling of videos via a simple, parameter efficient, and interpretable approach.
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