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Main Authors: Farooq, Junaid, Rafiq, Danish, Vlachas, Pantelis R., Bazaz, Mohammad Abid
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2401.13282
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author Farooq, Junaid
Rafiq, Danish
Vlachas, Pantelis R.
Bazaz, Mohammad Abid
author_facet Farooq, Junaid
Rafiq, Danish
Vlachas, Pantelis R.
Bazaz, Mohammad Abid
contents Forecasting complex system dynamics, particularly for long-term predictions, is persistently hindered by error accumulation and computational burdens. This study presents RefreshNet, a multiscale framework developed to overcome these challenges, delivering an unprecedented balance between computational efficiency and predictive accuracy. RefreshNet incorporates convolutional autoencoders to identify a reduced order latent space capturing essential features of the dynamics, and strategically employs multiple recurrent neural network (RNN) blocks operating at varying temporal resolutions within the latent space, thus allowing the capture of latent dynamics at multiple temporal scales. The unique "refreshing" mechanism in RefreshNet allows coarser blocks to reset inputs of finer blocks, effectively controlling and alleviating error accumulation. This design demonstrates superiority over existing techniques regarding computational efficiency and predictive accuracy, especially in long-term forecasting. The framework is validated using three benchmark applications: the FitzHugh-Nagumo system, the Reaction-Diffusion equation, and Kuramoto-Sivashinsky dynamics. RefreshNet significantly outperforms state-of-the-art methods in long-term forecasting accuracy and speed, marking a significant advancement in modeling complex systems and opening new avenues in understanding and predicting their behavior.
format Preprint
id arxiv_https___arxiv_org_abs_2401_13282
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle RefreshNet: Learning Multiscale Dynamics through Hierarchical Refreshing
Farooq, Junaid
Rafiq, Danish
Vlachas, Pantelis R.
Bazaz, Mohammad Abid
Machine Learning
Artificial Intelligence
Forecasting complex system dynamics, particularly for long-term predictions, is persistently hindered by error accumulation and computational burdens. This study presents RefreshNet, a multiscale framework developed to overcome these challenges, delivering an unprecedented balance between computational efficiency and predictive accuracy. RefreshNet incorporates convolutional autoencoders to identify a reduced order latent space capturing essential features of the dynamics, and strategically employs multiple recurrent neural network (RNN) blocks operating at varying temporal resolutions within the latent space, thus allowing the capture of latent dynamics at multiple temporal scales. The unique "refreshing" mechanism in RefreshNet allows coarser blocks to reset inputs of finer blocks, effectively controlling and alleviating error accumulation. This design demonstrates superiority over existing techniques regarding computational efficiency and predictive accuracy, especially in long-term forecasting. The framework is validated using three benchmark applications: the FitzHugh-Nagumo system, the Reaction-Diffusion equation, and Kuramoto-Sivashinsky dynamics. RefreshNet significantly outperforms state-of-the-art methods in long-term forecasting accuracy and speed, marking a significant advancement in modeling complex systems and opening new avenues in understanding and predicting their behavior.
title RefreshNet: Learning Multiscale Dynamics through Hierarchical Refreshing
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2401.13282