English

Classical versus Quantum: comparing Tensor Network-based Quantum Circuits on LHC data

Quantum Physics 2022-12-20 v2 Machine Learning High Energy Physics - Experiment High Energy Physics - Phenomenology

Abstract

Tensor Networks (TN) are approximations of high-dimensional tensors designed to represent locally entangled quantum many-body systems efficiently. This study provides a comprehensive comparison between classical TNs and TN-inspired quantum circuits in the context of Machine Learning on highly complex, simulated LHC data. We show that classical TNs require exponentially large bond dimensions and higher Hilbert-space mapping to perform comparably to their quantum counterparts. While such an expansion in the dimensionality allows better performance, we observe that, with increased dimensionality, classical TNs lead to a highly flat loss landscape, rendering the usage of gradient-based optimization methods highly challenging. Furthermore, by employing quantitative metrics, such as the Fisher information and effective dimensions, we show that classical TNs require a more extensive training sample to represent the data as efficiently as TN-inspired quantum circuits. We also engage with the idea of hybrid classical-quantum TNs and show possible architectures to employ a larger phase-space from the data. We offer our results using three main TN ansatz: Tree Tensor Networks, Matrix Product States, and Multi-scale Entanglement Renormalisation Ansatz.

Keywords

Cite

@article{arxiv.2202.10471,
  title  = {Classical versus Quantum: comparing Tensor Network-based Quantum Circuits on LHC data},
  author = {Jack Y. Araz and Michael Spannowsky},
  journal= {arXiv preprint arXiv:2202.10471},
  year   = {2022}
}

Comments

18 pages, 15 figures, 1 table. Accepted version for publication in PRA

R2 v1 2026-06-24T09:48:31.902Z