We describe how simple machine learning methods successfully predict geometric properties from Hilbert series (HS). Regressors predict embedding weights in projective space to ∼1 mean absolute error, whilst classifiers predict dimension and Gorenstein index to >90% accuracy with ∼0.5% standard error. Binary random forest classifiers managed to distinguish whether the underlying HS describes a complete intersection with high accuracies exceeding 95%. Neural networks (NNs) exhibited success identifying HS from a Gorenstein ring to the same order of accuracy, whilst generation of 'fake' HS proved trivial for NNs to distinguish from those associated to the three-dimensional Fano varieties considered.
@article{arxiv.2103.13436,
title = {Hilbert Series, Machine Learning, and Applications to Physics},
author = {Jiakang Bao and Yang-Hui He and Edward Hirst and Johannes Hofscheier and Alexander Kasprzyk and Suvajit Majumder},
journal= {arXiv preprint arXiv:2103.13436},
year = {2022}
}
Comments
10 pages; v2: principle component analysis added; v3: minor corrections