COMPARISON OF AI TURBULENCE PREDICTION PERFORMANCE ACROSS TIME SCALE: A COMPARATIVE STUDY OF U-NET AND DIFFUSION MODEL

J. Kang; M. Oh; J. Jeon; S. Lee

doi:10.6112/kscfe.2026.31.1.079

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Original Article

COMPARISON OF AI TURBULENCE PREDICTION PERFORMANCE ACROSS TIME SCALE: A COMPARATIVE STUDY OF U-NET AND DIFFUSION MODEL 시간 간격에 따른 인공지능 난류 예측 성능 비교: U-Net과 Diffusion Model의 비교 연구

31 March 2026. pp. 79-89

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Abstract

This study investigates the impact of time increments on the autoregressive prediction of two-dimensional turbulence slices extracted from three-dimensional direct numerical simulations, comparing a U-Net with a diffusion-based generative model. Experiments demonstrate that the diffusion model significantly outperforms the deterministic approach, reducing the rollout-averaged mean squared error by 28.3% and relative energy error by 61.9%. Notably, the generative model effectively mitigates the smoothing of fine-scale structures and error accumulation observed in deterministic methods, preserving physical statistics such as energy spectra even at large time steps. Although the diffusion-based approach incurs higher computational costs, these findings highlight its superior capability in maintaining physical consistency for long-term turbulence prediction under partial observation conditions.

Keywords

Turbulence prediction

Diffusion models

Autoregressive forecasting

Time-step optimization

키워드

난류 예측

확산 모델

자기회귀 예측

시간간격 최적화

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Information

Publisher :Korean Society for Computational Fluids Engineering
Publisher(Ko) :한국전산유체공학회
Journal Title :Journal of Computational Fluids Engineering
Journal Title(Ko) :한국전산유체공학회지
Volume : 31
No :1
Pages :79-89
Received Date : 2026-03-03
Revised Date : 2026-03-23
Accepted Date : 2026-03-23
DOI :https://doi.org/10.6112/kscfe.2026.31.1.079

Journal of Computational Fluids Engineering ISSN:1598-6071(Print) 3022-6252(Online) 한국전산유체공학회지

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