English

Constraining Black Hole Parameters in Non-Commutative Geometry using Machine Learning

General Relativity and Quantum Cosmology 2026-05-25 v1 High Energy Physics - Theory

Abstract

Motivated by string theory, we constrain non-commutative black hole parameters through shadow behaviors using machine learning techniques combined by CUDA computations. To do so, we first investigate the structure of the event horizon of non-commutative black holes in the presence of string clouds and dark energy sectors by exploiting CUDA-based methods. We numerically approach the shadow properties and the energy emission rate of rotating and charged black holes in non-commutative geometry via such high-performance parallel computings. To bridge these findings with observational data, we implement a CUDA-based framework in order to constrain the involved black hole parameters including the non-commutative one. Using the resulting numerical data, we build a robust training datasets for a fully connected neural network to determine whether a given set of parameters matches with the observational data provided by Event Horizon Telescope collaborations. As a result, we find that the non-commutative model under study is consistent with the observations of SgrAKeckSgrA^*_{\mathrm{Keck}} black holes.

Keywords

Cite

@article{arxiv.2605.22862,
  title  = {Constraining Black Hole Parameters in Non-Commutative Geometry using Machine Learning},
  author = {Maryem Jemri},
  journal= {arXiv preprint arXiv:2605.22862},
  year   = {2026}
}

Comments

30 pages, 11 figures, 6 tables, LaTeX