Traditional fluid flow predictions require large computational resources. Despite recent progress in parallel and GPU computing, the ability to run fluid flow predictions in real-time is often infeasible. Recently developed machine learning approaches, which are trained on high-fidelity data, perform unsatisfactorily outside the training set and remove the ability of utilising legacy codes after training. We propose a novel methodology that uses a deep learning approach that can be used within a low-fidelity fluid flow solver to significantly increase the accuracy of the low-fidelity simulations. The resulting solver enables accurate while reducing computational times up to 100 times. The deep neural network is trained on a combinati...
This paper presents a novel generative model to synthesize fluid simulations from a set of reduced p...
The usage of neural networks (NNs) for flow reconstruction (FR) tasks from a limited number of senso...
In recent years, the evolution of artificial intelligence, especially deep learning, has been remark...
Traditional fluid flow predictions require large computational resources. Despite recent progress i...
The modeling of complex physical and biological phenomena has long been the domain of computational ...
In recent years, deep learning has opened countless research opportunities across many different dis...
It is the tradition for the fluid community to study fluid dynamics problems via numerical simulatio...
Data sets for the two numerical examples in the paper Multi-fidelity Generative Deep Learning Turbul...
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...
Physics-informed neural network (PINN) architectures are recent developments that can act as surroga...
Historically, numerical analysis has formed the backbone of supercomputing for decades by applying m...
State-of-the-art neural network models estimate large displacement optical flow in multi-resolution ...
Recently, physics-driven deep learning methods have shown particular promise for the prediction of p...
Information loss in numerical physics simulations can arise from various sources when solving discre...
This paper presents a novel generative model to synthesize fluid simulations from a set of reduced p...
The usage of neural networks (NNs) for flow reconstruction (FR) tasks from a limited number of senso...
In recent years, the evolution of artificial intelligence, especially deep learning, has been remark...
Traditional fluid flow predictions require large computational resources. Despite recent progress i...
The modeling of complex physical and biological phenomena has long been the domain of computational ...
In recent years, deep learning has opened countless research opportunities across many different dis...
It is the tradition for the fluid community to study fluid dynamics problems via numerical simulatio...
Data sets for the two numerical examples in the paper Multi-fidelity Generative Deep Learning Turbul...
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...
Physics-informed neural network (PINN) architectures are recent developments that can act as surroga...
Historically, numerical analysis has formed the backbone of supercomputing for decades by applying m...
State-of-the-art neural network models estimate large displacement optical flow in multi-resolution ...
Recently, physics-driven deep learning methods have shown particular promise for the prediction of p...
Information loss in numerical physics simulations can arise from various sources when solving discre...
This paper presents a novel generative model to synthesize fluid simulations from a set of reduced p...
The usage of neural networks (NNs) for flow reconstruction (FR) tasks from a limited number of senso...
In recent years, the evolution of artificial intelligence, especially deep learning, has been remark...