Quantum Computational Complexity and Symmetry
Abstract
Testing the symmetries of quantum states and channels provides a way to assess their usefulness for different physical, computational, and communication tasks. Here, we establish several complexity-theoretic results that classify the difficulty of symmetry-testing problems involving a unitary representation of a group and a state or a channel that is being tested. In particular, we prove that various such symmetry-testing problems are complete for BQP, QMA, QSZK, QIP(2), QIP_EB(2), and QIP, thus spanning the prominent classes of the quantum interactive proof hierarchy and forging a non-trivial connection between symmetry and quantum computational complexity. Finally, we prove the inclusion of two Hamiltonian symmetry-testing problems in QMA and QAM, while leaving it as an intriguing open question to determine whether these problems are complete for these classes.
Cite
@article{arxiv.2309.10081,
title = {Quantum Computational Complexity and Symmetry},
author = {Soorya Rethinasamy and Margarite L. LaBorde and Mark M. Wilde},
journal= {arXiv preprint arXiv:2309.10081},
year = {2025}
}
Comments
28 pages, 10 figures, 1 table, submission to the journal special issue honoring A. Ravi P. Rau