Learning nonlinear operators in latent spaces for real-time predictions of complex dynamics in physical systems

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Abstract

Predicting complex dynamics in physical applications governed by partial differential equations in real-time is nearly impossible with traditional numerical simulations due to high computational cost. Neural operators offer a solution by approximating mappings between infinite-dimensional Banach spaces, yet their performance degrades with system size and complexity. We propose an approach for learning neural operators in latent spaces, facilitating real-time predictions for highly nonlinear and multiscale systems on high-dimensional domains. Our method utilizes the deep operator network architecture on a low-dimensional latent space to efficiently approximate underlying operators. Demonstrations on material fracture, fluid flow prediction, and climate modeling highlight superior prediction accuracy and computational efficiency compared to existing methods. Notably, our approach enables approximating large-scale atmospheric flows with millions of degrees, enhancing weather and climate forecasts. Here we show that the proposed approach enables real-time predictions that can facilitate decision-making for a wide range of applications in science and engineering.

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Kontolati, K., Goswami, S., Em Karniadakis, G., & Shields, M. D. (2024). Learning nonlinear operators in latent spaces for real-time predictions of complex dynamics in physical systems. Nature Communications, 15(1). https://doi.org/10.1038/s41467-024-49411-w

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