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On Quantum Learning Advantage Under Symmetries

Quantum Physics 2026-02-04 v2

Abstract

Symmetry underlies many of the most effective classical and quantum learning algorithms, yet whether quantum learners can gain a fundamental advantage under symmetry-imposed structures remains an open question. Based on evidence that classical statistical query (\SQ\SQ) frameworks have revealed exponential query complexity in learning symmetric function classes, we ask: can quantum learning algorithms exploit the problem symmetry better? In this work, we investigate the potential benefits of symmetry within the quantum statistical query (\QSQ\QSQ) model, which is a natural quantum analog of classical \SQ\SQ. Our results uncover three distinct phenomena: (i) we obtain an exponential separation between \QSQ\QSQ and \SQ\SQ on a permutation-invariant function class; (ii) we establish query complexity lower bounds for \QSQ\QSQ learning that match, up to constant factors, the corresponding classical \SQ\SQ lower bounds for most commonly studied symmetries; however, the potential advantages may occur under highly skewed orbit distributions; and (iii) we further identify a tolerance-based separation exists, where quantum learners succeed at noise levels that render classical \SQ\SQ algorithms ineffective. Together, these findings provide insight into when symmetry can enable quantum advantage in learning.

Keywords

Cite

@article{arxiv.2602.02008,
  title  = {On Quantum Learning Advantage Under Symmetries},
  author = {Tuyen Nguyen and Mária Kieferová and Amira Abbas},
  journal= {arXiv preprint arXiv:2602.02008},
  year   = {2026}
}

Comments

24 pages

R2 v1 2026-07-01T09:31:39.814Z