Data-Augmented Predictive Deep Neural Network: Enhancing the extrapolation capabilities of non-intrusive surrogate models

S Sun, L Feng, P Benner - arXiv preprint arXiv:2410.13376, 2024 - arxiv.org
arXiv preprint arXiv:2410.13376, 2024arxiv.org
Numerically solving a large parametric nonlinear dynamical system is challenging due to its
high complexity and the high computational costs. In recent years, machine-learning-aided
surrogates are being actively researched. However, many methods fail in accurately
generalizing in the entire time interval $[0, T] $, when the training data is available only in a
training time interval $[0, T_0] $, with $ T_0< T $. To improve the extrapolation capabilities of
the surrogate models in the entire time domain, we propose a new deep learning framework …
Numerically solving a large parametric nonlinear dynamical system is challenging due to its high complexity and the high computational costs. In recent years, machine-learning-aided surrogates are being actively researched. However, many methods fail in accurately generalizing in the entire time interval , when the training data is available only in a training time interval , with . To improve the extrapolation capabilities of the surrogate models in the entire time domain, we propose a new deep learning framework, where kernel dynamic mode decomposition (KDMD) is employed to evolve the dynamics of the latent space generated by the encoder part of a convolutional autoencoder (CAE). After adding the KDMD-decoder-extrapolated data into the original data set, we train the CAE along with a feed-forward deep neural network using the augmented data. The trained network can predict future states outside the training time interval at any out-of-training parameter samples. The proposed method is tested on two numerical examples: a FitzHugh-Nagumo model and a model of incompressible flow past a cylinder. Numerical results show accurate and fast prediction performance in both the time and the parameter domain.
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