English

Predicting Ground State Properties: Constant Sample Complexity and Deep Learning Algorithms

Quantum Physics 2024-11-05 v2 Machine Learning Computational Physics

Abstract

A fundamental problem in quantum many-body physics is that of finding ground states of local Hamiltonians. A number of recent works gave provably efficient machine learning (ML) algorithms for learning ground states. Specifically, [Huang et al. Science 2022], introduced an approach for learning properties of the ground state of an nn-qubit gapped local Hamiltonian HH from only nO(1)n^{\mathcal{O}(1)} data points sampled from Hamiltonians in the same phase of matter. This was subsequently improved by [Lewis et al. Nature Communications 2024], to O(logn)\mathcal{O}(\log n) samples when the geometry of the nn-qubit system is known. In this work, we introduce two approaches that achieve a constant sample complexity, independent of system size nn, for learning ground state properties. Our first algorithm consists of a simple modification of the ML model used by Lewis et al. and applies to a property of interest known beforehand. Our second algorithm, which applies even if a description of the property is not known, is a deep neural network model. While empirical results showing the performance of neural networks have been demonstrated, to our knowledge, this is the first rigorous sample complexity bound on a neural network model for predicting ground state properties. We also perform numerical experiments that confirm the improved scaling of our approach compared to earlier results.

Keywords

Cite

@article{arxiv.2405.18489,
  title  = {Predicting Ground State Properties: Constant Sample Complexity and Deep Learning Algorithms},
  author = {Marc Wanner and Laura Lewis and Chiranjib Bhattacharyya and Devdatt Dubhashi and Alexandru Gheorghiu},
  journal= {arXiv preprint arXiv:2405.18489},
  year   = {2024}
}

Comments

11 pages, 7 figures + 40-page appendix

R2 v1 2026-06-28T16:44:36.060Z