Add to ORKGNumerical simulators are essential tools in the study of natural fluid-systems, but their performance often limits application in practice. Recent machine-learning approaches have demonstrated their ability to accelerate spatio-temporal predictions, although, with only moderate accuracy in comparison. Here we introduce MultiScaleGNN, a novel multi-scale graph neural network model for learning to infer unsteady continuum mechanics in problems encompassing a range of length scales and complex boundary geometries. We demonstrate this method on advection problems and incompressible fluid dynamics, both fundamental phenomena in oceanic and atmospheric processes. Our results show good extrapolation to new domain geometries and parameters for long...
Simulating complex physical systems often involves solving partial differential equations (PDEs) wit...
We propose the geometry-informed neural operator (GINO), a highly efficient approach to learning the...
Recent works on learning-based frameworks for Lagrangian (i.e., particle-based) fluid simulation, th...
Numerical simulation of multi-phase fluid dynamics in porous media is critical for many subsurface a...
Recent advances in statistical and machine learning have opened the possibility of forecasting the b...
International audienceThe ubiquity of fluids in the physical world explains the need to accurately s...
In recent years, the development of deep learning is noticeably influencing the progress of computat...
The modeling of complex physical and biological phenomena has long been the domain of computational ...
Numerical simulation is an essential tool in many areas of science and engineering, but its performa...
Using convolutional neural networks, deep learning-based reduced-order models have demonstrated grea...
We present a novel physics-informed deep learning framework for solving steady-state incompressible ...
One of the main challenges in using deep learning-based methods for simulating physical systems and ...
Abundance of measurement and simulation data has led to the proliferation of machine learning tools ...
Fourier neural operators (FNOs) are a recently introduced neural network architecture for learning s...
The multi-scale nature of gaseous flows poses tremendous difficulties for theoretical and numerical ...
Simulating complex physical systems often involves solving partial differential equations (PDEs) wit...
We propose the geometry-informed neural operator (GINO), a highly efficient approach to learning the...
Recent works on learning-based frameworks for Lagrangian (i.e., particle-based) fluid simulation, th...
Numerical simulation of multi-phase fluid dynamics in porous media is critical for many subsurface a...
Recent advances in statistical and machine learning have opened the possibility of forecasting the b...
International audienceThe ubiquity of fluids in the physical world explains the need to accurately s...
In recent years, the development of deep learning is noticeably influencing the progress of computat...
The modeling of complex physical and biological phenomena has long been the domain of computational ...
Numerical simulation is an essential tool in many areas of science and engineering, but its performa...
Using convolutional neural networks, deep learning-based reduced-order models have demonstrated grea...
We present a novel physics-informed deep learning framework for solving steady-state incompressible ...
One of the main challenges in using deep learning-based methods for simulating physical systems and ...
Abundance of measurement and simulation data has led to the proliferation of machine learning tools ...
Fourier neural operators (FNOs) are a recently introduced neural network architecture for learning s...
The multi-scale nature of gaseous flows poses tremendous difficulties for theoretical and numerical ...
Simulating complex physical systems often involves solving partial differential equations (PDEs) wit...
We propose the geometry-informed neural operator (GINO), a highly efficient approach to learning the...
Recent works on learning-based frameworks for Lagrangian (i.e., particle-based) fluid simulation, th...