PDE foundation models are skillful AI weather emulators for the Martian atmosphere
This work provides a more efficient AI weather emulator for the Martian atmosphere, addressing data and compute limitations in planetary science.
The researchers tackled the problem of predicting Martian weather by adapting a pretrained PDE foundation model to three dimensions, achieving a 34.4% performance increase on held-out data.
We show that AI foundation models that are pretrained on numerical solutions to a diverse corpus of partial differential equations can be adapted and fine-tuned to obtain skillful predictive weather emulators for the Martian atmosphere. We base our work on the Poseidon PDE foundation model for two-dimensional systems. We develop a method to extend Poseidon from two to three dimensions while keeping the pretraining information. Moreover, we investigate the performance of the model in the presence of sparse initial conditions. Our results make use of four Martian years (approx.~34 GB) of training data and a median compute budget of 13 GPU hours. We find that the combination of pretraining and model extension yields a performance increase of 34.4\% on a held-out year. This shows that PDEs-FMs can not only approximate solutions to (other) PDEs but also anchor models for real-world problems with complex interactions that lack a sufficient amount of training data or a suitable compute budget.