MLMOD: Machine Learning Methods for Data-Driven Modeling in LAMMPS
- URL: http://arxiv.org/abs/2107.14362v2
- Date: Sat, 21 Oct 2023 00:51:03 GMT
- Title: MLMOD: Machine Learning Methods for Data-Driven Modeling in LAMMPS
- Authors: Paul J. Atzberger
- Abstract summary: We present a prototype C++/Python package for characterizing microscale mechanics and molecular dynamics.
The package is integrated currently with the mesomod and molecular dynamics simulation package LAMMPS and PyTorch.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: MLMOD is a software package for incorporating machine learning approaches and
models into simulations of microscale mechanics and molecular dynamics in
LAMMPS. Recent machine learning approaches provide promising data-driven
approaches for learning representations for system behaviors from experimental
data and high fidelity simulations. The package faciliates learning and using
data-driven models for (i) dynamics of the system at larger spatial-temporal
scales (ii) interactions between system components, (iii) features yielding
coarser degrees of freedom, and (iv) features for new quantities of interest
characterizing system behaviors. MLMOD provides hooks in LAMMPS for (i)
modeling dynamics and time-step integration, (ii) modeling interactions, and
(iii) computing quantities of interest characterizing system states. The
package allows for use of machine learning methods with general model classes
including Neural Networks, Gaussian Process Regression, Kernel Models, and
other approaches. Here we discuss our prototype C++/Python package, aims, and
example usage. The package is integrated currently with the mesocale and
molecular dynamics simulation package LAMMPS and PyTorch. For related papers,
examples, updates, and additional information see
https://github.com/atzberg/mlmod and http://atzberger.org/.
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