COMPOL: A Unified Neural Operator Framework for Scalable Multi-Physics Simulations
- URL: http://arxiv.org/abs/2501.17296v3
- Date: Fri, 19 Sep 2025 22:31:31 GMT
- Title: COMPOL: A Unified Neural Operator Framework for Scalable Multi-Physics Simulations
- Authors: Yifei Sun, Tao Wang, Junqi Qu, Yushun Dong, Hewei Tang, Shibo Li,
- Abstract summary: COMPOL is a novel coupled multiphysics operator learning framework.<n>It incorporates sophisticated recurrent and attentionbased aggregation mechanisms effectively modeling interdependencies among interacting physical processes within latent feature spaces.<n>It consistently achieves superior predictive accuracy compared to stateoftheart methods.
- Score: 21.983719504206878
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Multiphysics simulations play an essential role in accurately modeling complex interactions across diverse scientific and engineering domains Although neural operators especially the Fourier Neural Operator FNO have significantly improved computational efficiency they often fail to effectively capture intricate correlations inherent in coupled physical processes To address this limitation we introduce COMPOL a novel coupled multiphysics operator learning framework COMPOL extends conventional operator architectures by incorporating sophisticated recurrent and attentionbased aggregation mechanisms effectively modeling interdependencies among interacting physical processes within latent feature spaces Our approach is architectureagnostic and seamlessly integrates into various neural operator frameworks that involve latent space transformations Extensive experiments on diverse benchmarksincluding biological reactiondiffusion systems patternforming chemical reactions multiphase geological flows and thermohydromechanical processes demonstrate that COMPOL consistently achieves superior predictive accuracy compared to stateoftheart methods.
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