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Representation Theory for Geometric Quantum Machine Learning

Quantum Physics 2023-02-08 v2 Machine Learning Representation Theory Machine Learning

Abstract

Recent advances in classical machine learning have shown that creating models with inductive biases encoding the symmetries of a problem can greatly improve performance. Importation of these ideas, combined with an existing rich body of work at the nexus of quantum theory and symmetry, has given rise to the field of Geometric Quantum Machine Learning (GQML). Following the success of its classical counterpart, it is reasonable to expect that GQML will play a crucial role in developing problem-specific and quantum-aware models capable of achieving a computational advantage. Despite the simplicity of the main idea of GQML -- create architectures respecting the symmetries of the data -- its practical implementation requires a significant amount of knowledge of group representation theory. We present an introduction to representation theory tools from the optics of quantum learning, driven by key examples involving discrete and continuous groups. These examples are sewn together by an exposition outlining the formal capture of GQML symmetries via "label invariance under the action of a group representation", a brief (but rigorous) tour through finite and compact Lie group representation theory, a reexamination of ubiquitous tools like Haar integration and twirling, and an overview of some successful strategies for detecting symmetries.

Keywords

Cite

@article{arxiv.2210.07980,
  title  = {Representation Theory for Geometric Quantum Machine Learning},
  author = {Michael Ragone and Paolo Braccia and Quynh T. Nguyen and Louis Schatzki and Patrick J. Coles and Frederic Sauvage and Martin Larocca and M. Cerezo},
  journal= {arXiv preprint arXiv:2210.07980},
  year   = {2023}
}

Comments

43 pages, 10 figures. Updated to add relevant references

R2 v1 2026-06-28T03:40:25.323Z