In this study, we propose an encoder–decoder convolutional neural network-based approach for estimating the pressure field around an airfoil. The developed tool is one of the early steps of a machine-learning-based aerodynamic performance prediction tool. Network training and evaluation are performed from a set of computational fluid dynamics (CFD)-based solutions of the 2-D flow field around a group of known airfoils involving symmetrical, cambered, thick and thin airfoils. Reynolds averaged Navier Stokes-based CFD simulations are performed at a selected single Mach number and for an angle of attack condition. The calculated pressure field, which is the main parameter for lift and drag calculations, is fed to the neural network training al...
Physics-informed machine learning is a novel approach to solving flow problems with physics-informed...
Understanding of flow dynamics is crucial in a comprehensive set of scientific disciplines, such as ...
This research is supported by the projects GA21-31457S ”Fast flow-field prediction using deep neura...
project "Centre of research and experimental development of reliable energy production" TE01020068 o...
Many applications use symmetric or asymmetric airfoils, such as aircraft design, wind turbines, and ...
A study to analyze the efficacy of two novel, state-of-the-art deep learning methods used in flow-fi...
This study aims to predict flow fields around airfoils using a deep learning methodology based on an...
Learning from data offers new opportunities for developing computational methods in research fields,...
This work proposes a novel multi-output neural network for the prediction of the lift coefficient of...
Aircraft design requires a multitude of aerodynamic data and providing this solely based on high-qua...
Wind energy has become an important source of electricity generation, with the aim of achieving a cl...
The numerical analysis of aerodynamic components based on the Reynolds Average Navier Stokes equatio...
New generation combat aircraft are expected to operate over extended flight envelopes, including fli...
In a myriad of engineering situations, we often hope to establish a model which can acquire load con...
This work proposes a novel multi-output neural network for the prediction of the aerodynamic coeffic...
Physics-informed machine learning is a novel approach to solving flow problems with physics-informed...
Understanding of flow dynamics is crucial in a comprehensive set of scientific disciplines, such as ...
This research is supported by the projects GA21-31457S ”Fast flow-field prediction using deep neura...
project "Centre of research and experimental development of reliable energy production" TE01020068 o...
Many applications use symmetric or asymmetric airfoils, such as aircraft design, wind turbines, and ...
A study to analyze the efficacy of two novel, state-of-the-art deep learning methods used in flow-fi...
This study aims to predict flow fields around airfoils using a deep learning methodology based on an...
Learning from data offers new opportunities for developing computational methods in research fields,...
This work proposes a novel multi-output neural network for the prediction of the lift coefficient of...
Aircraft design requires a multitude of aerodynamic data and providing this solely based on high-qua...
Wind energy has become an important source of electricity generation, with the aim of achieving a cl...
The numerical analysis of aerodynamic components based on the Reynolds Average Navier Stokes equatio...
New generation combat aircraft are expected to operate over extended flight envelopes, including fli...
In a myriad of engineering situations, we often hope to establish a model which can acquire load con...
This work proposes a novel multi-output neural network for the prediction of the aerodynamic coeffic...
Physics-informed machine learning is a novel approach to solving flow problems with physics-informed...
Understanding of flow dynamics is crucial in a comprehensive set of scientific disciplines, such as ...
This research is supported by the projects GA21-31457S ”Fast flow-field prediction using deep neura...