apax
[1] is a high-performance, extendable package for training of and inference with atomistic neural networks.
It implements the Gaussian Moment Neural Network model [2, 3].
It is based on JAX and uses JaxMD as a molecular dynamics engine.
Apax is available on PyPI with a CPU version of JAX.
pip install apax
For more detailed instructions, please refer to the documentation.
If you want to enable GPU support (only on Linux), please overwrite the jaxlib version:
CUDA 12:
pip install -U "jax[cuda12]"
See the Jax installation instructions for more details.
In order to train a model, you need to run
apax train config.yaml
We offer some input file templates to get new users started as quickly as possible. Simply run the following commands and add the appropriate entries in the marked fields
apax template train # use --full for a template with all input options
Please refer to the documentation for a detailed explanation of all parameters.
The documentation can convenienty be accessed by running apax docs
.
There are two ways in which apax
models can be used for molecular dynamics out of the box.
High performance NVT simulations using JaxMD can be started with the CLI by running
apax md config.yaml md_config.yaml
A template command for MD input files is provided as well.
The second way is to use the ASE calculator provided in apax.md
.
use the following command to generate JSON schemata for training and MD configuration files:
apax schema
If you are using VSCode, you can utilize them to lint and autocomplete your input files.
The command creates the 2 schemata and adds them to the projects .vscode/settings.json
- Moritz René Schäfer
- Nico Segreto
Under the supervion of Johannes Kästner
We are happy to receive your issues and pull requests!
Do not hesitate to contact any of the authors above if you have any further questions.
The creation of Apax was supported by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) in the framework of the priority program SPP 2363, “Utilization and Development of Machine Learning for Molecular Applications - Molecular Machine Learning” Project No. 497249646 and the Ministry of Science, Research and the Arts Baden-Württemberg in the Artificial Intelligence Software Academy (AISA). Further funding though the DFG under Germany's Excellence Strategy - EXC 2075 - 390740016 and the Stuttgart Center for Simulation Science (SimTech) was provided.
- [1] 10.5281/zenodo.10040711
- [2] V. Zaverkin and J. Kästner, “Gaussian Moments as Physically Inspired Molecular Descriptors for Accurate and Scalable Machine Learning Potentials,” J. Chem. Theory Comput. 16, 5410–5421 (2020).
- [3] V. Zaverkin, D. Holzmüller, I. Steinwart, and J. Kästner, “Fast and Sample-Efficient Interatomic Neural Network Potentials for Molecules and Materials Based on Gaussian Moments,” J. Chem. Theory Comput. 17, 6658–6670 (2021).