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Autori principali: Esmati, Parsa, Dadashzadeh, Amirhossein, Goodarzi, Vahid, Larrosa, Nicolas, Grilli, Nicolò
Natura: Preprint
Pubblicazione: 2024
Soggetti:
Accesso online:https://arxiv.org/abs/2410.15495
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author Esmati, Parsa
Dadashzadeh, Amirhossein
Goodarzi, Vahid
Larrosa, Nicolas
Grilli, Nicolò
author_facet Esmati, Parsa
Dadashzadeh, Amirhossein
Goodarzi, Vahid
Larrosa, Nicolas
Grilli, Nicolò
contents Current approaches using sequential networks have shown promise in estimating field variables for dynamical systems, but they are often limited by high rollout errors. The unresolved issue of rollout error accumulation results in unreliable estimations as the network predicts further into the future, with each step's error compounding and leading to an increase in inaccuracy. Here, we introduce the State-Exchange Attention (SEA) module, a novel transformer-based module enabling information exchange between encoded fields through multi-head cross-attention. The cross-field multidirectional information exchange design enables all state variables in the system to exchange information with one another, capturing physical relationships and symmetries between fields. Additionally, we introduce an efficient ViT-like mesh autoencoder to generate spatially coherent mesh embeddings for a large number of meshing cells. The SEA integrated transformer demonstrates the state-of-the-art rollout error compared to other competitive baselines. Specifically, we outperform PbGMR-GMUS Transformer-RealNVP and GMR-GMUS Transformer, with a reduction in error of 88% and 91%, respectively. Furthermore, we demonstrate that the SEA module alone can reduce errors by 97% for state variables that are highly dependent on other states of the system. The repository for this work is available at: https://github.com/ParsaEsmati/SEA
format Preprint
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publishDate 2024
record_format arxiv
spellingShingle SEA: State-Exchange Attention for High-Fidelity Physics Based Transformers
Esmati, Parsa
Dadashzadeh, Amirhossein
Goodarzi, Vahid
Larrosa, Nicolas
Grilli, Nicolò
Machine Learning
Artificial Intelligence
Current approaches using sequential networks have shown promise in estimating field variables for dynamical systems, but they are often limited by high rollout errors. The unresolved issue of rollout error accumulation results in unreliable estimations as the network predicts further into the future, with each step's error compounding and leading to an increase in inaccuracy. Here, we introduce the State-Exchange Attention (SEA) module, a novel transformer-based module enabling information exchange between encoded fields through multi-head cross-attention. The cross-field multidirectional information exchange design enables all state variables in the system to exchange information with one another, capturing physical relationships and symmetries between fields. Additionally, we introduce an efficient ViT-like mesh autoencoder to generate spatially coherent mesh embeddings for a large number of meshing cells. The SEA integrated transformer demonstrates the state-of-the-art rollout error compared to other competitive baselines. Specifically, we outperform PbGMR-GMUS Transformer-RealNVP and GMR-GMUS Transformer, with a reduction in error of 88% and 91%, respectively. Furthermore, we demonstrate that the SEA module alone can reduce errors by 97% for state variables that are highly dependent on other states of the system. The repository for this work is available at: https://github.com/ParsaEsmati/SEA
title SEA: State-Exchange Attention for High-Fidelity Physics Based Transformers
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2410.15495