2020
DOI: 10.1016/j.cma.2019.112732
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Surrogate modeling for fluid flows based on physics-constrained deep learning without simulation data

Abstract: Numerical simulations on fluid dynamics problems primarily rely on spatially or/and temporally discretization of the governing equation using polynomials into a finite-dimensional algebraic system. Due to the multi-scale nature of the physics and sensitivity from meshing a complicated geometry, such process can be computational prohibitive for most realtime applications (e.g., clinical diagnosis and surgery planning) and many-query analyses (e.g., optimization design and uncertainty quantification). Therefore,… Show more

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Cited by 652 publications
(317 citation statements)
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References 70 publications
(88 reference statements)
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“…The approaches cited above all require numerical simulation data to train the neural network. In physics informed surrogate models [9,10,11,12,13], by contrast, simulation data are not needed for training. With these procedures the governing partial differential equations (PDEs) are approximated by formulating PDE residuals, along with the initial and boundary conditions, as the objective function to be minimized by the neural network [14].…”
Section: Introductionmentioning
confidence: 99%
“…The approaches cited above all require numerical simulation data to train the neural network. In physics informed surrogate models [9,10,11,12,13], by contrast, simulation data are not needed for training. With these procedures the governing partial differential equations (PDEs) are approximated by formulating PDE residuals, along with the initial and boundary conditions, as the objective function to be minimized by the neural network [14].…”
Section: Introductionmentioning
confidence: 99%
“…This process, also known as the 'learning' or 'training' phase, is an iterative optimisation procedure aimed at minimising errors between the real data and those predicted by the algorithm. This approach works successfully for computer vision tasks, for example, due to an abundance of labelled data and the interpolatory nature of the problem (Sun et al 2019). However, the application of off-the-shelf ML techniques to flow dynamics problems (or any other physical phenomena for that matter) inevitably suffers from non-interpretability in terms of governing physics due to ML's 'black-box' nature.…”
Section: Introductionmentioning
confidence: 99%
“…The loss function of the pix2pix architecture in a conditional GAN [217], [218] was penalized by using a constraint enforcing module for spatial sensitivity analysis for predicting urban land use [219]. The loss of a fully connected NN was made to include boundary conditions and residuals of the governing equations for surrogate modeling in hemodynamics [220]. Reinforcement learning was also used for learning non-parametric models under constrained state spaces in continuous environments [221].…”
Section: Physics Based Regularizationmentioning
confidence: 99%