A GPU-accelerated differentiable simulation toolbox for additive manufacturing (AM) based on JAX.
JAX-AM is a collection of several numerical tools, currently including Discrete Element Method (DEM), Lattice Boltzmann Methods (LBM), Computational Fluid Dynamics (CFD), Phase Field Method (PFM) and Finite Element Method (FEM), that cover the analysis of the Process-Structure-Property relationship in AM.
Our vision is to share with the AM community a free, open-source (under the GPL-3.0 License) software that facilitates the relevant computational research. In the JAX ecosystem, we hope to emphasize the potential of JAX for scientific computing. At the same time, AI-enabled research in AM can be made easy with JAX-AM.
🔥 Join us for the development of JAX-AM!
DEM simulation can be used for simulating powder dynamics in metal AM.
Free falling of 64,000 spherical particles.
LBM can simulate melt pool dynamics with a free-surface model.
A powder bed fusion process considering surface tension, Marangoni effect and recoil pressure.
CFD helps to understand the AM process by solving the (incompressible) Navier-Stokes equations for velocity, pressure and temperature.
Melt pool dynamics.
PFM models the grain development that is critical to form the structure of the as-built sample.
Microstructure evolution.
Directional solidification with isotropic (left) and anisotropic (right) grain growth.
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Check JAX-FEM. This is a design decision that aims to push the FEM module into a general-purpose, independent package that works for problems beyond additive manufacturing. Therefore, the code related to FEM in this repository (JAX-AM) will NOT be updated in the future.
Please see the web documentation for the installation and use of this project.
This project is licensed under the GNU General Public License v3 - see the LICENSE for details.
If you found this library useful in academic or industry work, we appreciate your support if you consider 1) starring the project on Github, and 2) citing relevant papers:
@article{xue2023jax,
title={JAX-FEM: A differentiable GPU-accelerated 3D finite element solver for automatic inverse design and mechanistic data science},
author={Xue, Tianju and Liao, Shuheng and Gan, Zhengtao and Park, Chanwook and Xie, Xiaoyu and Liu, Wing Kam and Cao, Jian},
journal={Computer Physics Communications},
pages={108802},
year={2023},
publisher={Elsevier}
}
@article{xue2022physics,
title={Physics-embedded graph network for accelerating phase-field simulation of microstructure evolution in additive manufacturing},
author={Xue, Tianju and Gan, Zhengtao and Liao, Shuheng and Cao, Jian},
journal={npj Computational Materials},
volume={8},
number={1},
pages={201},
year={2022},
publisher={Nature Publishing Group UK London}
}