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Autores principales: Yu, Linqi, Yousif, Mustafa Z., Zhou, Dan, Zhang, Meng, Lee, Jungsub, Lim, Hee-Chang
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2408.01659
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author Yu, Linqi
Yousif, Mustafa Z.
Zhou, Dan
Zhang, Meng
Lee, Jungsub
Lim, Hee-Chang
author_facet Yu, Linqi
Yousif, Mustafa Z.
Zhou, Dan
Zhang, Meng
Lee, Jungsub
Lim, Hee-Chang
contents In this study, we proposed an efficient approach based on a deep learning (DL) denoising autoencoder (DAE) model for denoising noisy flow fields. The DAE operates on a self-learning principle and does not require clean data as training labels. Furthermore, investigations into the denoising mechanism of the DAE revealed that its bottleneck structure with a compact latent space enhances denoising efficacy. Meanwhile, we also developed a deep multiscale DAE for denoising turbulent flow fields. Furthermore, we used conventional noise filters to denoise the flow fields and performed a comparative analysis with the results from the DL method. The effectiveness of the proposed DL models was evaluated using direct numerical simulation data of laminar flow around a square cylinder and turbulent channel flow data at various Reynolds numbers. For every case, synthetic noise was augmented in the data. A separate experiment used particle-image velocimetry data of laminar flow around a square cylinder containing real noise to test DAE denoising performance. Instantaneous contours and flow statistical results were used to verify the alignment between the denoised data and ground truth. The findings confirmed that the proposed method could effectively denoise noisy flow data, including turbulent flow scenarios. Furthermore, the proposed method exhibited excellent generalization, efficiently denoising noise with various types and intensities.
format Preprint
id arxiv_https___arxiv_org_abs_2408_01659
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Self-Supervised Learning for Effective Denoising of Flow Fields
Yu, Linqi
Yousif, Mustafa Z.
Zhou, Dan
Zhang, Meng
Lee, Jungsub
Lim, Hee-Chang
Fluid Dynamics
In this study, we proposed an efficient approach based on a deep learning (DL) denoising autoencoder (DAE) model for denoising noisy flow fields. The DAE operates on a self-learning principle and does not require clean data as training labels. Furthermore, investigations into the denoising mechanism of the DAE revealed that its bottleneck structure with a compact latent space enhances denoising efficacy. Meanwhile, we also developed a deep multiscale DAE for denoising turbulent flow fields. Furthermore, we used conventional noise filters to denoise the flow fields and performed a comparative analysis with the results from the DL method. The effectiveness of the proposed DL models was evaluated using direct numerical simulation data of laminar flow around a square cylinder and turbulent channel flow data at various Reynolds numbers. For every case, synthetic noise was augmented in the data. A separate experiment used particle-image velocimetry data of laminar flow around a square cylinder containing real noise to test DAE denoising performance. Instantaneous contours and flow statistical results were used to verify the alignment between the denoised data and ground truth. The findings confirmed that the proposed method could effectively denoise noisy flow data, including turbulent flow scenarios. Furthermore, the proposed method exhibited excellent generalization, efficiently denoising noise with various types and intensities.
title Self-Supervised Learning for Effective Denoising of Flow Fields
topic Fluid Dynamics
url https://arxiv.org/abs/2408.01659