Very complex flows can be expensive to compute using current CFD techniques. In this thesis, models based on deep learning were used to replace certain parts of the flow domain, with the objective of replacing well-known regions with simplified models to increase efficiency. To keep the error produced by the deep learning model bounded, a traditional CFD model and deep learning model were coupled using a boundary overlap area. In this overlap area, the flow computed by the traditional CFD model was used by the deep learning model as an input. It was demonstrated that since traditional CFD model continuously feeds in reliable information into the deep learning domain, the error remains bounded. Furthermore, it was found that the accuracy of ...
It is the tradition for the fluid community to study fluid dynamics problems via numerical simulatio...
As early as at the end of the 19th century, shortly after mathematical rules describing fluid flow—s...
This dataset is used for the paper “Deep learning for subgrid-scale turbulence modeling in large-edd...
A study to analyze the efficacy of two novel, state-of-the-art deep learning methods used in flow-fi...
The modeling of complex physical and biological phenomena has long been the domain of computational ...
Computational fluid dynamics (CFD) is the de-facto method for solving the Navier-Stokes equations, t...
The main objective of this thesis was to explore the capabilities of neural networks in terms of rep...
We use deep learning techniques to model computational fluid dynamics (CFD) simulations of wind flow...
In recent years, deep learning has opened countless research opportunities across many different dis...
The computational cost and memory demand required by computational fluid dynamics (CFD) codes simula...
A super-resolution reconstruction model for the subgrid scale (SGS) turbulent flow field in large-ed...
During each aircraft program a vast amount of aerodynamics data has to be generated to judge perform...
This paper presents a novel model reduction method: deep learning reduced order model, which is base...
Active flow control has the potential of achieving remarkable drag reductions in applications for fl...
This work presents data-driven predictions of nonlinear dynamical systems involving unsteady flow an...
It is the tradition for the fluid community to study fluid dynamics problems via numerical simulatio...
As early as at the end of the 19th century, shortly after mathematical rules describing fluid flow—s...
This dataset is used for the paper “Deep learning for subgrid-scale turbulence modeling in large-edd...
A study to analyze the efficacy of two novel, state-of-the-art deep learning methods used in flow-fi...
The modeling of complex physical and biological phenomena has long been the domain of computational ...
Computational fluid dynamics (CFD) is the de-facto method for solving the Navier-Stokes equations, t...
The main objective of this thesis was to explore the capabilities of neural networks in terms of rep...
We use deep learning techniques to model computational fluid dynamics (CFD) simulations of wind flow...
In recent years, deep learning has opened countless research opportunities across many different dis...
The computational cost and memory demand required by computational fluid dynamics (CFD) codes simula...
A super-resolution reconstruction model for the subgrid scale (SGS) turbulent flow field in large-ed...
During each aircraft program a vast amount of aerodynamics data has to be generated to judge perform...
This paper presents a novel model reduction method: deep learning reduced order model, which is base...
Active flow control has the potential of achieving remarkable drag reductions in applications for fl...
This work presents data-driven predictions of nonlinear dynamical systems involving unsteady flow an...
It is the tradition for the fluid community to study fluid dynamics problems via numerical simulatio...
As early as at the end of the 19th century, shortly after mathematical rules describing fluid flow—s...
This dataset is used for the paper “Deep learning for subgrid-scale turbulence modeling in large-edd...