Abstract
In this paper, we propose a general framework for projection-based model order reduction assisted by deep neural networks. The proposed methodology, called ROM-net, consists in using deep learning techniques to adapt the reduced-order model to a stochastic input tensor whose nonparametrized variabilities strongly influence the quantities of interest for a given physics problem. In particular, we introduce the concept of dictionary-based ROM-nets, where deep neural networks recommend a suitable local reduced-order model from a dictionary. The dictionary of local reduced-order models is constructed from a clustering of simplified simulations enabling the identification of the subspaces in which the solutions evolve for different input tensors. The training examples are represented by points on a Grassmann manifold, on which distances are computed for clustering. This methodology is applied to an anisothermal elastoplastic problem in structural mechanics, where the damage field depends on a random temperature field. When using deep neural networks, the selection of the best reduced-order model for a given thermal loading is 60 times faster than when following the clustering procedure used in the training phase.
Highlights
Numerical simulations in physics have become an essential tool in many engineering domains
Our objective is to define a general framework for reduced-order model adaptation using deep neural networks, in order to see to what extent model order reduction can benefit from the recent advances in deep learning
The computation time for the selection of the best reduced-order model is decreased by a factor of 60 when using the ROM-net’s deep classifier FK instead of the true classifier KK
Summary
Numerical simulations in physics have become an essential tool in many engineering domains. The development of high-performance computing has enabled engineers and scientists to use complex models for real-world applications, with ultra-realistic simulations involving millions of degrees of freedom. Such simulations are too time-consuming to be integrated in design iterations in the industry. They are usually limited to the final validation and certification steps, while the design process still relies on simplified models. Accelerating these complex simulations is a key challenge, as it would provide useful numerical tools to improve design processes.
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