This is an impementation of Variational Monte Carlo (VMC) for quantum many-body dynamics using the JAX library (and Flax on top) to exploit the blessings of automatic differentiation for easy model composition and just-in-time compilation for execution on accelerators.
Please report bugs as well as other issues or suggestions on our issues page.
Documentation is available here.
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We recommend you create a new conda environment to work with jVMC:
conda create -n jvmc python=3.8 conda activate jvmc -
pip-install the packagepip install jVMC
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Clone the jVMC repository and check out the development branch:
git clone https://github.com/markusschmitt/vmc_jax.git cd vmc_jax -
We recommend you create a new conda environment to work with jVMC:
conda create -n jvmc python=3.8 conda activate jvmc -
pip-install the packagepip install .Alternatively, for development:
pip install -e .[dev]
Test that everything worked, e.g. run 'python -c "import jVMC"' from a place different than vmc_jax.
How to compile JAX on a supercomputing cluster
Click on the badge above to open a notebook that implements an exemplary ground state search in Google Colab.
Memory requirements grow with increasing network sizes. To avoid out-of-memory issues, the batchSize parameter of the NQS class has to be adjusted. The batchSize indicates on how many input configurations the network is evaluated concurrently. Out-of-memory issues are usually resolved by reducing this number. The numChains parameter of the Sampler class for Markov Chain Monte Carlo sampling plays a similar role, but its optimal values in terms of computational speed are typically not memory critical.
If you use the jVMC package for your research, please cite our reference paper SciPost Phys. Codebases 2 (2022).